EP3518658A1 - Parthenocarpic watermelon plants - Google Patents
Parthenocarpic watermelon plantsInfo
- Publication number
- EP3518658A1 EP3518658A1 EP17783787.9A EP17783787A EP3518658A1 EP 3518658 A1 EP3518658 A1 EP 3518658A1 EP 17783787 A EP17783787 A EP 17783787A EP 3518658 A1 EP3518658 A1 EP 3518658A1
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- EP
- European Patent Office
- Prior art keywords
- plant
- seq
- wopl
- allele
- mutant
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
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Classifications
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01H—NEW PLANTS OR NON-TRANSGENIC PROCESSES FOR OBTAINING THEM; PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
- A01H5/00—Angiosperms, i.e. flowering plants, characterised by their plant parts; Angiosperms characterised otherwise than by their botanic taxonomy
- A01H5/08—Fruits
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01H—NEW PLANTS OR NON-TRANSGENIC PROCESSES FOR OBTAINING THEM; PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
- A01H1/00—Processes for modifying genotypes ; Plants characterised by associated natural traits
- A01H1/06—Processes for producing mutations, e.g. treatment with chemicals or with radiation
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01H—NEW PLANTS OR NON-TRANSGENIC PROCESSES FOR OBTAINING THEM; PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
- A01H6/00—Angiosperms, i.e. flowering plants, characterised by their botanic taxonomy
- A01H6/32—Crassulaceae
- A01H6/324—Kalanchoe
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01H—NEW PLANTS OR NON-TRANSGENIC PROCESSES FOR OBTAINING THEM; PLANT REPRODUCTION BY TISSUE CULTURE TECHNIQUES
- A01H6/00—Angiosperms, i.e. flowering plants, characterised by their botanic taxonomy
- A01H6/34—Cucurbitaceae, e.g. bitter melon, cucumber or watermelon
- A01H6/342—Citrullus lanatus [watermelon]
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K14/00—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
- C07K14/415—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from plants
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/79—Vectors or expression systems specially adapted for eukaryotic hosts
- C12N15/82—Vectors or expression systems specially adapted for eukaryotic hosts for plant cells, e.g. plant artificial chromosomes (PACs)
- C12N15/8201—Methods for introducing genetic material into plant cells, e.g. DNA, RNA, stable or transient incorporation, tissue culture methods adapted for transformation
- C12N15/8213—Targeted insertion of genes into the plant genome by homologous recombination
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/79—Vectors or expression systems specially adapted for eukaryotic hosts
- C12N15/82—Vectors or expression systems specially adapted for eukaryotic hosts for plant cells, e.g. plant artificial chromosomes (PACs)
- C12N15/8241—Phenotypically and genetically modified plants via recombinant DNA technology
- C12N15/8261—Phenotypically and genetically modified plants via recombinant DNA technology with agronomic (input) traits, e.g. crop yield
- C12N15/8287—Phenotypically and genetically modified plants via recombinant DNA technology with agronomic (input) traits, e.g. crop yield for fertility modification, e.g. apomixis
Definitions
- the present invention is directed to facultative parthenocarpic watermelon plants, producing seedless fruits without pollination of the female flowers, due to the presence of a mutant allele of a recessive gene referred to as WOPl (for WithOutPapa 1).
- WOPl for WithOutPapa 1
- the present invention also comprises methods for production of said plants and the use of the mutant allele, referred to as wopl, for the production of seedless watermelon fruits.
- the invention also relates to other facultative parthenocarpic plants, such as cucumber and melon.
- Seedless fruits are e.g. known for watermelon, tomato, cucumber, eggplant, grapes, banana, citrus fruits, such as orange, lemon and lime. As consumption of seedless fruits is generally easier and more convenient, they are considered valuable.
- Fruit development normally begins when one or more egg cells in the ovular compartment of the flower are fertilized by sperm nuclei from pollen.
- Seedless fruits can result from two different phenomena. In some cases fruit develops without fertilization of the ovule by pollen, a phenomenon known as parthenocarpy. In other cases seedless fruits occur after pollination when seed (embryo and/or endosperm) growth is inhibited or the seed dies early, while the remainder of the fruit continues to grow (stenospermocarpy). In contrast to parthenocarpy, stenospermocarpy requires pollination for initiation of fruit growth.
- Seedless orange fruits are an example for parthenocarpy. Some orange varieties (e.g. Navel) do not produce viable pollen. They however can be cross-pollinated with pollen from other varieties. In case only the male sterile variety is grown in an orchard, there will be no pollination and parthenocarp seedless fruits will be produced. Propagation of the respective orange trees is commonly done by cuttings followed by grafting to another rootstock.
- Seedless bananas are triploid. Although pollination in some cases can be normal the vast majority of fruits is seedless. This is explained by the uneven sets of chromosomes (3x) leading to improper division of chromosomes during meiosis and as a consequence to the production of non- viable pollen. Without fertilization, triploid bananas are also able to set and develop seedless fruits. Even when pollination takes place, at most one in three hundred fruits comprises a few seeds. This may be due to the triploid pollen being non- viable, for the reasons explained. Therefore, banana plants can in general be seen to be parthenocarpic. Banana plants are commonly propagated asexually from side shoots or suckers at the base of the main stalk, which can be removed and replanted to continue the cultivar. Growers also propagate bananas by means of tissue culture, in particular for producing disease free material.
- Seedless cucumber, seedless squash and seedless eggplant are examples for crops which can produce seedless fruits without pollination (parthenocarpy), e.g. under conditions where pollination is impaired (e.g. low temperatures). Nevertheless, commercial quality fruit can be produced under these conditions. All these crops however can produce seed bearing fruits upon pollination. Therefore, these crops are facultative parthenocarpic. Propagation of the crops can be done by self- or cross pollination, in vitro propagation, and grafting. From tomato mutants it is also known that they can produce seedless fruits under conditions where normal pollination/fertilization is impaired (e.g. under circumstances of low temperature). Thus, these mutants are also facultative parthenocarpic.
- Seedless fruit producing watermelons are hybrids produced by crossing a male diploid (2n) watermelon plant with a female tetraploid (4n) watermelon plant.
- the resulting Fl hybrid seeds are triploid (3n). Induction of fruit setting of the triploid Fl hybrid plants requires pollination.
- the pollinator plants are diploid (2n). Generally a ratio of pollinator to hybrid plants of around 1 to 3 must be planted in a given scheme for providing sufficient pollen for pollinating all the Fl hybrid plants.
- the cross-pollination between the diploid (2n) pollinator and the flowers of the female triploid (3n) hybrid plant induces fruit set and leads to the production of seedless triploid fruits on the triploid hybrid plant.
- the diploid (2n) and tetraploid (4n) parents of the Fl hybrid each produce seed bearing fruits and can both be propagated independently from each other by self-pollination.
- Seedless grapes can be produced from plants being either parthenocarp or stenospermocarp.
- the variety Black Corinth is parthenocarp, whereas Sultanina is stenospermocarp. Vine plants are in general propagated by cuttings and successive grafting to another rootstock.
- Irregularities in meiosis can be a factor leading to plants producing seedless fruit.
- An example for plants producing seedless fruits is given in Zhang et al. (2012, Scientia Horticulture 140, 107-114), disclosing seedless watermelons.
- a male and female sterile (MFS) mutant was obtained from the progeny of a Fl- hybrid after irradiation of its seeds with gamma-rays. Pollen from the MFS mutant was not viable at all. Seedless fruits are produced by the MFS plants, when pollinated with pollen from male fertile plants. The MFS watermelon plant therefore can be classified as being stenospermocarpic.
- Ovules were also nearly entirely non- viable, as almost no seeds were produced upon cross-pollination of MFS mutants with pollen from different male fertile plants. Incomplete synapsis and abnormal separation of chromatids during meiosis were observed in the MFS mutant and seen to be the cause of male and female sterility. The genes responsible for the effects present in the MFS mutant have not been identified but it seems likely that the phenotype in the MFS mutant is due to a single recessive gene.
- stenospermocarpic crops such as triploid (3n) watermelon plants
- a female flower part of a plant must be pollinated.
- the stenospermocarpic crops grown today are male sterile.
- a different male fertile plant (pollinator or polliniser) has to be grown in addition in the same field.
- the area used for the pollinator plants is at the expense of the area which is available for the seedless fruit producing female plants, the yield per area under cultivation is reduced.
- the pollinator plants are normal plants which can also be self- pollinated. Fruits produced by pollinator plants however do produce seeds.
- the pollinator plants are normally diploid (2n), which upon self-pollination produce seeded fruits, which may in some instances also be harvested and sold separately (see WO2012069539). For commercial reasons these seeded fruits from the pollinator plants must not be mixed with the seedless fruits. Therefore, it has to be ensured, that seedless fruits and seeded fruits are separated upon or after harvest, which may make machine harvesting difficult or impossible or require a further processing step after harvesting. Those additional precautions to be taken increase the input costs in seedless fruit production. In addition, pollinator plants are developed so that they flower and produce sufficient viable pollen at the same time the female plant flowers and its stigma can accept pollen for the induction of fruit set.
- the pollinator plant has to fit with the female plant producing seedless fruit in respect to flowering and fertilisation time. If flowering time of the pollinator pant and the respective female plant is not sufficiently synchronised, pollination will not take place or only take place in an unsufficient amount of cases. As a result fewer fruits are produced by the stenospermocarpic female plant. Furthermore, it is well known in the art that climate conditions, like rain, heat etc., may influence pollen production of a polliniser plant differently than stigma fertility time of the genotypic different female plant. Therefore, climate conditions can also lead to asynchrony of fertility time of pollinator and female plant with the effect of lowering the yield.
- the present inventors have found that mutating a single recessive gene in cultivated watermelon, referred herein to as the WOPl gene, results in the watermelon plants developing seedless fruits when the flowers are not pollinated, i.e. parthenocarpy. If the flowers are pollinated, the fruits that develop produce normal viable seeds. This type of parthenocarpy is therefore referred to as facultative parthenocarpy, as it is only seen in the absence of pollination.
- the WOPl gene is, therefore, responsible for facultative parthenocarpy in watermelon.
- the mutant wopl allele when present in homozygous form in a diploid watermelon plant, indicated herein as wopl /wopl, the plants are facultative parthenocarp and produce seedless fruits from non-pollinated flowers and normal seeded fruits from pollinated flowers.
- This gene has great advantages in diploid watermelons, especially if combined with male sterility (MS) to ensure absence of pollination of the female flowers (as the male flowers produced on the plant are sterile) or combined with the embl mutant (in homozygous form, embl/embl) to ensure that, in case pollination does occur, the fruits are seedless due to the homozygous presence of the embl mutant in the plant.
- the embl mutant is a stenospermocarpy mutant, resulting in seedless fruits being produced upon pollination. Seeds comprising an embl mutant allele have been deposited by Nunhems B.V. on 27 January 2016 under accession number NCIMB42532.
- the WOPl gene has also great advantages in triploid watermelons having three copies of the mutant allele ⁇ wopl /wopl /wopl) because there is no need anymore to interplant such triploid watermelon plants with a pollenizer plant (which is normally needed to induce fruit set in normal tripoids, having three copies of the wild type WOPl allele).
- These parthenocarp triploid plants produce seedless fruits without the need for pollination to induce fruit set. Therefore basically the stenospermocarp nature of the normal triploid watermelons is changed into parthenocarpy. Yield of seedless triploid fruits is thereby increased greatly, as the pollenizer plants are not required anymore in a field and the entire field can comprise triploid watermelon plants.
- a mapping population was generated and the WOPl locus was mapped to a region of cultivated watermelon chromosome 4 starting at 14.4 Mb (SNP3) and ending at 18.9 Mb (SNP23) of chromosome 4, i.e. a region of approximately 4.5Mb in size (see Figure 2).
- the chromosome 4 region comprising the WOPl locus (and the mutant wopl allele or wild type WOPl allele) is defined herein by single nucleotide polymorphism (SNP) markers spanning the region between SNP3 and SNP23 and also the wider region between SNPl and SNP24 (starting at 11.9 Mb and ending at 21.8 Mb) and even between SNPla and SNP24 (starting at 8.3 Mb and ending at 21.8 Mb).
- SNP single nucleotide polymorphism
- WOPl gene sequence including the genomic sequence of the mutant wopl allele and the wild type WOPl allele.
- the WOPl gene is found in the region between SNP16 and SNP17.
- the WOPl gene is linked to SNP16a or SEQ ID NO: 30 or a nucleotide sequence comprising at least 95% sequence identity to SEQ ID NO: 30 and comprising the SNP nucleotide linked to the mutant (Adenine at nucleotide 428 of SEQ ID NO: 30).
- the WOPl gene is the gene encoding a WOPl protein, wherein a WOPl protein is the protein of SEQ ID NO: 32 or a protein comprising at least 95% sequence identity to SEQ ID NO: 32. Putative orthologs of WOPl were identified for cucumber and melon.
- a plant or plant cell characterized in that the plant or plant cell has decreased activity of a WOPl protein compared to a corresponding wild type plant cell, wherein the WOPl protein of the wild type plant cell is encoded by nucleic acid molecules selected from the group consisting of: a) nucleic acid molecules, which encode a protein with the amino acid sequence given under SEQ ID NO: 32 (watermelon) or SEQ ID NO: 33 (cucumber) or SEQ ID NO: 34 (melon);
- nucleic acid molecules which encode a protein, the sequence of which has an identity of at least 95%, 96%, 97% or 98% with the amino acid sequence given under SEQ ID NO: 32 (watermelon) or SED ID NO: 33 (cucumber) or SEQ ID NO: 34 (melon);
- nucleic acid molecules which encode a protein, the sequence of which has an identity of at least 95%, 96%, 97% or 98% with the amino acid sequence given under SEQ ID NO: 32
- the decreased activity of the WOPl protein is caused by a mutant wopl allele.
- Decreased activity may be caused by a knock-down or knock-out of the expression of the mutant wopl allele (e.g. through a mutation in the promoter or other regulatory sequence) or through the mutant wopl allele encoding a loss-of-function or decreased-function WOPl protein (mutant WOPl protein).
- the mutant wopl allele encodes a mutant WOPl protein having decreased function or loss- of-function compared to the wild type protein, e.g.
- the mutant WOPl protein comprises one or more amino acids replaced, deleted or inserted compared to the wild type protein.
- the mutant WOPl protein comprises one or more amino acids replaced, deleted or inserted in the conserved "myb like DNA binding domain, SHAQKYF” and/or in the "SHAQKYF” domain of the protein.
- at least one amino acid in the conserved "myb like DNA binding domain, SHAQKYF” and/or in the "SHAQKYF” domain is replaced, resulting in a loss of function or decreased function protein and facultative parthenocarpy when the allele is in homozygous form (when no wild type allele is present in the plant or plant cell).
- a cultivated watermelon plant or plant part comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form.
- the gene is located on chromosome 4, especially the gene is located in a region starting at base pair 11.906.147 and ending at base pair 21.897.585 of chromosome 4.
- said gene is located in a region starting at nucleotide 76 of SEQ ID NO: 1, or at nucleotide 76 of a sequence comprising at least 95% sequence identity to SEQ ID NO: 1, and ending at nucleotide 76 of SEQ ID NO: 24 or at nucleotide 76 of a sequence comprising at least 95% sequence identity to SEQ ID NO: 24.
- the gene is linked a nucleotide sequence selected from the group consisting of SEQ ID NO:
- SEQ ID NO: 1 or a sequence comprising at least 95% sequence identity to SEQ ID NO: 1 ;
- at least 95% sequence identity to SEQ ID NO : 3 SEQ ID NO 4 or a nucleotide sequence comprising ; at least 95% sequence identity to SEQ ID NO : 4,
- at least 95% sequence identity to SEQ ID NO : 6 SEQ ID NO 7 or a nucleotide sequence comprising ;
- at least 95% sequence identity to SEQ ID NO : 7 SEQ ID NO 8 or a nucleotide sequence comprising ;
- the gene is located between a pair of markers selected from the group consisting of SNPl and SNP3; SNP2 and SNP4; SNP3 and SNP5; SNP4 and SNP6; SNP5 and SNP7; SNP6 and SNP8; SNP7 and SNP9; SNP8 and SNP10; SNP9 and SNP11 ; SNP10 and SNP12; SNP11 and SNP13; SNPl 2 and SNP14; SNPl 3 and SNP15; SNPl 4 and SNPl 6; SNPl 5 and SNPl 7; SNPl 6 and SNPl 8; SNPl 7 and SNPl 9; SNPl 8 and SNP20; SNPl 9 and SNP21 ; SNP20 and SNP22; SNP21 and SNP23; SNP22 and SNP24.
- markers selected from the group consisting of SNPl and SNP3; SNP2 and SNP4; SNP3 and SNP5; SNP4 and SNP6; SNP5 and S
- the plant or plant part comprising the mutant allele of the WOP1 gene is diploid, tetraploid, triploid or polyploid.
- the mutant allele is present in two copies in a diploid plant or plant part, in four copies in a tetraploid plant or plant part or in three copies in a triploid plant or plant part.
- the mutant allele is the allele as found in seeds deposited under NCIMB42533 or progeny thereof.
- the plant or plant part further comprises a gene conferring male sterility or a gene conferring stenospermocarpy.
- the plant part comprising the mutant allele of the WOPl gene may be a cell, a flower, a leaf, a stem, a cutting, an ovule, pollen, a root, a rootstock, a scion, a fruit, a protoplast, an embryo, an anther.
- a seed from which a plant of the invention can be grown is provided. Further, a seedless fruit produced by a plant according to the invention is provided.
- a method of producing seedless watermelon fruits comprising growing a triploid plant comprising three copies of a mutant allele of a WOPl gene and harvesting the fruits produced by said plants.
- the fruits develop without pollination of the female flowers.
- a method for production of a facultative parthenocarpic cultivated watermelon plant comprising the steps of: a) introducing mutations in a population of watermelon plants; b) selecting a plant producing seedless fruits without pollination of the female flowers and producing a seeded fruit after pollination of the female flowers; c) optionally verifying if the plant selected under b) comprises a mutant allele of a WOPl gene on chromosome 4; and d) optionally growing the plants obtained under c).
- a watermelon plant produced by the method is encompassed herein.
- the term "plant” includes the whole plant or any parts or derivatives thereof, preferably having the same genetic makeup as the plant from which it is obtained, such as plant organs (e.g. harvested or non-harvested fruits, leaves, flowers, anthers, etc.), plant cells, plant protoplasts, plant cell tissue cultures from which whole plants can be regenerated, plant calli, plant cell clumps, plant transplants, seedlings, plant cells that are intact in plants, plant clones or micropropagations, or parts of plants, such as plant cuttings, embryos, pollen, anthers, ovules, fruits (e.g.
- seeds of a plant refer to seeds from which the plant can be grown or to seeds produced on the plant, after self-fertilization or cross-fertilization.
- the term "variety” or “cultivar” means a plant grouping within a single botanical taxon of the lowest known rank, which can be defined by the expression of the characteristics resulting from a given genotype or combination of genotypes.
- allele(s) means any of one or more alternative forms of a gene at a particular locus, e.g. the WOP1 locus (where the WOP1 gene is located; the alleles of the gene may be wild type alleles designated WOP1, or mutant alleles designated wopl), all of which alleles relate to one trait or characteristic at a specific locus (e.g. facultative parthenocarpy).
- WOP1 locus where the WOP1 gene is located; the alleles of the gene may be wild type alleles designated WOP1, or mutant alleles designated wopl), all of which alleles relate to one trait or characteristic at a specific locus (e.g. facultative parthenocarpy).
- WOP1 locus where the WOP1 gene is located; the alleles of the gene may be wild type alleles designated WOP1, or mutant alleles designated wopl
- alleles of a given gene are located at a specific location, or locus (loci plural) on a
- a diploid plant species may comprise a large number of different alleles at a particular locus. These may be identical alleles of the gene (homozygous) or two different alleles (heterozygous), e.g. two identical copies of the mutant wopl allele (i.e. wopl/wopl) or one copy of the mutant wopl allele and one copy of the wild type allele ( i.e. wopl/WOPl). Likewise a triploid plant is referred to as homozygous for the gene if it has three identical alleles of a gene (e.g. three copies of the mutant wopl allele, i.e.
- wopl /wopl /wopl and a tetraploid plant is referred to as homozygous for the gene if it has four identical alleles of the gene, e.g. four copies of the mutant wopl allele (i.e. wopl /wopl /wopl /wopl).
- "WOPl gene” is a single, recessive gene identified in cultivated watermelon on chromosome 4, which when mutated results in parthenocarpy, especially facultative parthenocarpy.
- WOPl is the wild type (WT), functional allele as present in non-parthenocarpic cultivated watermelon plants and wopl is the mutant allele resulting in parthenocarpy if the allele is in homozygous form in a diploid (wopl /wopl), triploid (wopl/wopl/wopl), tetraploid (wopl /wopl /wopl /wopl), or other polyploidy, e.g. octaploid (wopl /wopl /wopl /wopl /wopl /wopl /wopl /wopl) etc.
- WT wild type
- wopl is the mutant allele resulting in parthenocarpy if the allele is in homozygous form in a diploid (wopl /wopl), triploid (wopl/w
- the WOPl gene is the gene encoding a protein of SEQ ID NO: 32 or encoding a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32 (watermelon), when aligned pairwise.
- Parthenocarpy or “ parthenocarpic” is generally understood in the art and also to be understood in connection with the present invention to describe the development of fruits without fertilization of the female ovule. A pollination process is not needed for producing fruits which fruits however as a consequence of the lack of pollination are seedless.
- parthenocarpy means herein that fruits are formed on the plant without pollination of the female flowers.
- a “parthenocarpic plant” or a “plant comprising a mutant gene (or mutant allele of a gene) conferring parthenocarpy when in homozygous form” means that the plant produces seedless fruits without pollination of the female flowers.
- Fracultative parthenocarpy is understood to mean that the parthenocarpy trait is not seen when the flower of the facultative parthenocarpic plant is pollinated, in which case normal fertilization and normal fruit development takes place. As normal fertilization takes place, the fruits are seeded.
- Fl, F2, F3, etc. refers to the consecutive related generations following a cross between two parent plants or parent lines. The plants grown from the seeds produced by crossing two plants or lines is called the Fl generation. Selling the Fl plants results in the F2 generation, etc.
- Fl hybrid plant (or Fl hybrid seed) is the generation obtained from crossing two inbred parent lines.
- Fl hybrid seeds are seeds from which Fl hybrid plants grow.
- Fl hybrids are more vigorous and higher yielding, due to heterosis.
- Inbred lines are essentially homozygous at most loci in the genome.
- a “plant line” or “breeding line” refers to a plant and its progeny.
- the term “inbred line” refers to a plant line which has been repeatedly selfed and is nearly homozygous.
- an "inbred line” or “parent line” refers to a plant which has undergone several generations (e.g. at least 5, 6, 7 or more) of inbreeding, resulting in a plant line with a high uniformity.
- gene means a (genomic) DNA sequence comprising a region (transcribed region), which is transcribed into a messenger RNA molecule (mRNA) in a cell, and an operably linked regulatory region (e.g. a promoter).
- mRNA messenger RNA molecule
- WOPl operably linked regulatory region
- Different alleles of a gene are thus different alternatives form of the gene, which may be in the form of e.g. differences in one or more nucleotides of the genomic DNA sequence (e.g. in the promoter sequence, the exon sequences, intron sequences, etc.), mRNA and/or amino acid sequence of the encoded protein.
- mutant wopl allele or “wopl allele” refers herein to a mutant allele of the WOP1 gene on chromosome 4, which causes the plant to be facultative parthenocarpic when the mutant allele is in homozygous form.
- the mutation in the mutant allele can be any mutation or combination of mutations, including deletions, truncations, insertions, point mutations, non-sense mutations, mis-sense mutations or non-synonymous mutations, splice-site mutations, frame shift mutations and/or mutations in one or more regulatory sequences such as promoter sequence, or enhancer or silencer sequences.
- mutant wopl allele is the allele found in 25% of the seeds deposited under NCIMB42533 in homozygous form.
- the mutant wopl allele is a mutant allele of the WOP1 gene whereby the WOP1 gene is the gene encoding a protein of SEQ ID NO: 32 or encoding a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32 (when aligned pairwise).
- Wild type WOP1 allele or “WOP1 allele” refers herein to the functional allele of the WOP1 gene, which causes the plant to have a normal fruit set, requiring normal pollination and fertilization to set fruits.
- the wild type WOP1 allele is found in any commercial variety of watermelon (e.g. Nunhems variety Premium Fl, Montreal Fl, and others) and also in 25%> of the seeds deposited under NCIMB42533 in homozygous form.
- the wild type WOP1 allele is a wild type allele of the WOP1 gene whereby the WOP1 gene is the gene encoding a protein of SEQ ID NO: 32 or encoding a protein comprising at least 95%>, 96%>, 97%> or 98%> sequence identity to SEQ ID NO: 32 (when aligned pairwise).
- locus loci plural
- the WOP1 locus is, thus, the location in the genome of watermelon, where the mutant allele and/or the wild type allele of the WOP1 gene is found.
- the WOP1 locus is a locus on cultivated watermelon chromosome 4 (using the chromosome assignment of the published watermelon genome found at world wide web at icugi.org/cgi-bin/ICuGI/index.cgi under "Watermelon: Genome”, “Watermelon genome (97103) - version 1" and as described in Guo S, Zhang J, Sun H, Salse J, Lucas W, Zhang H, Zheng Y, Mao L, Ren Y, Wang Z (2013) "The draft genome of watermelon (Citrullus lanatus) and resequencing of 20 diverse accessions" (Nature Genetics 45:51-58) i.e.
- wopl was generated in the cultivated watermelon genome by mutagenesis and the mutant wopl allele was mapped to a defined region of chromosome 4 of cultivated watermelon.
- "Diploid plant” refers to a plant, vegetative plant part(s), or seed from which a diploid plant can be grown, having two sets of chromosome, designated herein as 2n.
- a “DH plant” or “doubled-haploid plant” is a diploid plant produced by doubling the haploid genome of the diploid plant using e.g. in vitro techniques. A DH plant is, therefore, homozygous at all loci.
- “Triploid plant” refers to a plant, vegetative plant part(s), or seed from which a triploid plant can be grown, having three sets of chromosomes, designated herein as 3n.
- Tetraploid plant refers to a plant, vegetative plant part(s), or seed from which a tetraploid plant can be grown, having four sets of chromosomes, designated herein as 4n.
- Polyploid plant refers to plants having a higher ploidy than diploid, i.e. triploid (3n), tetraploid (4n), hexaploid (6n), octaploid (8n), etc.
- Polylenizer plant or “pollenizer” refers to the (inbred or hybrid) diploid plant, or parts thereof (e.g. its pollen or scion), suitable as pollenizer for inducing fruit set on triploid plants.
- a pollenizer plant is, thus, able to lead to good fruit set (and good triploid fruit yield) of normal triploid plants (comprising three copies of the wild type WOP1 allele), by producing an appropriate amount of pollen at the appropriate day-time and for an appropriate period of time.
- Hybrid triploid plant or “Fl triploid” or “triploid hybrid” is a triploid plant grown from hybrid, triploid seed obtained from cross fertilizing a male diploid parent with a female tetraploid parent. The male parent is used for inducing fruit set and seed production on a tetraploid female parent, resulting in fruits containing Fl hybrid triploid seeds. Both the male parent and the female parent used to produce Fl triploid seeds are inbred so that each parent line is nearly homozygous and stable.
- “Seedless fruit” are fruits which contain no viable mature seeds.
- the fruit may contain one or more small, edible, white ovules, e.g. as seen in Figure 1A and 1C.
- the fruit may contain a few brown or black seeds, but these are not viable.
- Viable mature seeds are seeds which can be germinated in soil under appropriate conditions and grow into plants.
- Plant or “planted” refers to seeding (direct sowing) or transplanting seedlings (plantlets) into a field by machine or hand.
- “Vegetative propagation” or “clonal propagation” refers to propagation of plants from vegetative tissue, e.g. by in vitro propagation or grafting methods (using scions and rootstocks).
- In vitro propagation involves in vitro cell or tissue culture and regeneration of a whole plant from the in vitro culture.
- Grafting involves propagation of an original plant by grafting onto a rootstock. Clones (i.e. genetically identical vegetative propagations) of the original plant can thus be generated by either in vitro culture or grafting.
- “Cell culture” or “tissue culture” refers to the in vitro culture of cells or tissues of a plant.
- Regeneration refers to the development of a plant from cell culture or tissue culture or vegetative propagation.
- Non-propagating cell refers to a cell which cannot be regenerated into a whole plant.
- “Recessive” refers to an allele which expresses its phenotype (e.g. parthenocarpy or facultative parthenocarpy) when no dominant allele is present in the genome, i.e. when it is homozygous.
- the wopl allele according to the invention results in a (facultative) parthenocarp plant when present in homozygous form, i.e. in two copies in a diploid plant, in four copies in a tetraploid plant or in three copies in a triploid plant or in the respective number of copies in another polyploidy (e.g. 8 copies in an octaploid), whereby a dominant allele WOP1 allele is absent in these plants.
- the dominant allele is herein also referred to as the wild type (WT) allele.
- Cultivated watermelon or “Citrullus lanatus” refers herein to Citrullus lanatus ssp. vulgaris, or Citrullus lanatus (Thunb.) Matsum. & Nakai subsp. vulgaris (Schrad.), and having good agronomic characteristics, especially producing marketable fruits of good fruit quality and fruit uniformity.
- Cultivated cucumber and cultivated melon refer to Cucumis sativus and Cucumis melo plants having good agronomic characteristics, especially producing marketable fruits of good fruit quality and fruit uniformity.
- Wild watermelon refers herein to Citrullus lanatus ssp. lanatus and Citrullus lanatus ssp. mucosospermus , producing fruits of poor quality and poor uniformity.
- SNP marker refers to a Single Nucleotide Polymorphism between different cultivated watermelon lines and the SNP markers provided herein define the chromosome 4 region in which the WOP1 gene is found.
- SNP genotype refers to the nucleotide present at the particular SNP.
- SNP haplotype refers to a particular genotype at several SNPs. It is noted that the wopl mutant is a mutation in cultivated watermelon, not an introgression from a wild watermelon, meaning that the SNP genotype of the SNP marker linked to the WOP1 gene is not relevant as such (except where the SNP is in in one embodiment in the allele itself, e.g.
- SNP 16a the SNP genotype depends on the background breeding line, elite line or cultivar.
- the SNPs (the single nucleotide and/or the sequence comprising the SNP, or a variant sequence comprising at least 95% sequence identity to the given sequence) do however delimit the physical region on the chromosome 4 in which the WOP1 gene is found and can be used e.g. to distinguish plants comprising the mutant wopl allele from plants lacking the mutant wopl allele and having the wild type WOP I allele instead, in plants grown from NCIMB42533 or progeny thereof.
- “Cultivated watermelon genome” and “physical position on the cultivated watermelon genome” and “chromosome 4" refers to the physical genome of cultivated watermelon, world wide web at www.icugi.org/cgi-bin/ICuGI/index.cgi under “Watermelon: Genome”, “Watermelon genome (97103) - version 1" and the physical chromosomes and the physical position on the chromosomes.
- SNP 01 (at nucleotide 76 of SEQ ID NO: l) is located at the nucleotide (or 'base') positioned physically at nucleotide 11.906.147 of chromosome 4
- SNP 02 (at nucleotide 76 of SEQ ID NO: 2) is located at the nucleotide (or 'base') positioned physically at nucleotide 13.357.557 of chromosome 4
- SNP 03 (at nucleotide 76 of SEQ ID NO: 3) is located at the nucleotide (or 'base') positioned physically at nucleotide 14.402.485 of chromosome 4.
- Chromosome 4 has a physical size from 0 to 24.3 Mb.
- a "chromosome 4 region comprising the mutant wopl allele” refers to the genomic region of chromosome 4 of cultivated watermelon which region carries the mutant wopl allele.
- the presence of the allele can be determined phenotypically and/or by the presence of one or more molecular markers, e.g. SNP markers or other markers, linked to the wopl allele.
- a marker is "linked to the wopl allele", if it is physically coupled to the allele.
- a marker such as a SNP marker, (or a nucleotide sequence comprising a marker) is linked to the wopl allele if it is within a physical distance of 2.5 Mb or less, such as 2.0 Mb or less, 1.5Mb or less, 1.0 Mb or less, 0.8 Mb or less, 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less of the wopl allele.
- 2.5 Mb or less such as 2.0 Mb or less, 1.5Mb or less, 1.0 Mb or less, 0.8 Mb or less, 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb,
- a marker or a nucleotide sequence comprising a marker is "closely linked to the mutant wopl allele" if it is within a physical distance of 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less of the wopl allele.
- a pair of "flanking markers” refers to two markers, preferably two SNP markers or two sequences comprising the SNP markers, which are linked to the wopl allele, and/or which are closely linked to the wopl allele, whereby the wopl allele is located in-between the two markers or in-between the two sequences comprising the markers.
- “Brix” or “degree Brix” or “° brix” refers to the mean total soluble solids content as measured on several mature fruits using a refractometer. Preferably the mean of at least three fruits, each measured between the centre and the rind of the cut-open fruit, is calculated.
- “Marketable” in relation to fruit quality means that the watermelon fruits are suitable for being sold for fresh consumption, having good flavour (no off-flavours), a degree brix of at least 9.0, preferably at least 10.0 or at least 11.0 and preferably also a uniform fruit flesh color, being e.g. white (e.g. variety Cream of Saskatchewan), yellow (e.g. variety Yamato Cream 1), orange (e.g. variety Tendersweet), pink (e.g. variety Sadul), pinkish red (e.g. variety Crimson Sweet), red (e.g. variety Sugar Baby) or dark red (e.g. variety Dixie Lee).
- white e.g. variety Cream of Saskatchewan
- yellow e.g. variety Yamato Cream 1
- orange e.g. variety Tendersweet
- pink e.g. variety Sadul
- pinkish red e.g. variety Crimson Sweet
- red e.g. variety Sugar Baby
- dark red e.g. variety Dixie Lee
- Uniform fruit flesh color means that the color throughout the mature fruits, when cut open through the middle (midsection), is evenly distributed throughout the fruit flesh, i.e. not patchy. Thus, a red fruit is red throughout the fruit flesh and does not contain white patches.
- An example of a fruit with uniform red color is the diploid variety Premium Fl (Nunhems).
- “Physical distance” between loci (e.g. between molecular markers and/or between phenotypic markers) on the same chromosome is the actually distance expressed in bases or base pairs (bp), kilo bases or kilo base pairs (kb) or megabases or mega base pairs (Mb).
- Geneetic distance between loci is measured by frequency of crossing-over, or recombination frequency (RF) and is indicated in centimorgans (cM).
- RF recombination frequency
- cM centimorgans
- One cM corresponds to a recombination frequency of about 1%. If no recombinants can be found, the RF is zero and the loci are either extremely close together physically or they are identical. The further apart two loci are, the higher the RF.
- "Uniformity" or “uniform” relates to the genetic and phenotypic characteristics of a plant line or variety. Inbred lines are genetically highly uniform as they are produced by several generations of inbreeding. Likewise, and the Fl hybrids and the triploid hybrids which are produced from such inbred lines are highly uniform in their genotypic and phenotypic characteristics and performance.
- a genetic element, an introgression fragment, or a gene or allele conferring a trait (such as parthenocarpy) is said to be “obtainable from” or can be “obtained from” or “derivable from” or can be “derived from” or “as present in” or “as found in” a plant or seed or tissue or cell if it can be transferred from the plant or seed in which it is present into another plant or seed in which it is not present (such as a non-parthenocarp line or variety) using traditional breeding techniques without resulting in a phenotypic change of the recipient plant apart from the addition of the trait conferred by the genetic element, locus, introgression fragment, gene or allele.
- the terms are used interchangeably and the genetic element, locus, introgression fragment, gene or allele can thus be transferred into any other genetic background lacking the trait.
- seeds deposited and comprising the genetic element, locus, introgression fragment, gene or allele can be used, but also progeny/descendants from such seeds which have been selected to retain the genetic element, locus, introgression fragment, gene or allele, can be used and are encompassed herein, such as commercial varieties developed from the deposited seeds or from descendants or ancestors thereof.
- other cultivated watermelons containing the genetic element, locus, introgression fragment, gene or allele e.g. a mutant wopl allele
- can be generated de novo, e.g. by mutagenesis e.g.
- a plant or genomic DNA, cell or tissue of a plant
- locus or variant thereof
- introgression fragment, gene or allele as obtainable from the deposited seeds
- phenotypic assays whole genome sequencing, molecular marker analysis, trait mapping, chromosome painting, allelism tests and the like, or combinations of techniques.
- Average or “mean” refers herein to the arithmetic mean and both terms are used interchangeably.
- the term "average” or “mean” thus refers to the arithmetic mean of several measurements.
- the skilled person understands that the phenotype of a plant line or variety depends to some extent on growing conditions and that, therefore, arithmetic means of at least 10, 15, 20, 30, 40, 50 or more plants (or plant parts) are measured, preferably in randomized experimental designs with several replicates and suitable control plants grown under the same conditions in the same experiment.
- "Statistically significant” or “statistically significantly” different or “significantly” different refers to a characteristic of a plant line or variety that, when compared to a suitable control show a statistically significant difference in that characteristic (e.g. the p-value is less than 0.05, p ⁇ 0.05, using ANOVA) from the (mean of the) control.
- Backcrossing refers to a breeding method by which a (single) trait, such as the facultative parthenocarpy trait, can be transferred from one (often an inferior) genetic background (also referred to as “donor") into another (often a superior) genetic background (also referred to as "recurrent parent”.
- An offspring of a cross e.g. an Fl plant obtained by crossing e.g. the donor with the recurrent parent watermelon, or an F2 plant or F3 plant, etc., obtained from selling the Fl
- an offspring of a cross e.g. an Fl plant obtained by crossing e.g. the donor with the recurrent parent watermelon, or an F2 plant or F3 plant, etc., obtained from selling the Fl
- the trait of the one (often inferior) genetic background will have been incorporated into the other (often superior) genetic background.
- Marker assisted selection is a process of using the presence of molecular markers (such as SNP markers), which are genetically and physically linked to a particular locus or to a particular chromosome region, to select plants for the presence of the specific locus or region.
- molecular markers such as SNP markers
- a molecular marker genetically and physically linked to the mutant wopl allele can be used to detect and/or select watermelon plants, or plant parts, comprising the wopl allele.
- the closer the linkage of the molecular marker to the locus the less likely it is that the marker is dissociated from the locus through meiotic recombination.
- the closer two markers are linked to each other the less likely it is that the two markers will be separated from one another (and the more likely they will co-segregate as a unit).
- a molecular marker (or a sequence comprising a molecular marker) within 5 Mb, 3 Mb, 2.5 Mb, 2 Mb, 1 Mb, 0.5 Mb, 0.4Mb, 0.3Mb, 0.2Mb, 0.1 Mb, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less of another marker (or a sequence comprising the molecular marker), or of a locus, refers to a marker which is physically located within the 5 Mb, 3 Mb, 2.5 Mb, 2 Mb, 1 Mb, 0.5 Mb, 0.4Mb, 0.3Mb, 0.2Mb, 0.1 Mb, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less, of the genomic DNA region flanking the marker (i.e.
- LOD-score logarithm (base 10) of odds refers to a statistical test often used for linkage analysis in animal and plant populations. The LOD score compares the likelihood of obtaining the test data if the two loci (molecular marker loci and/or a phenotypic trait locus) are indeed linked, to the likelihood of observing the same data purely by chance. Positive LOD scores favor the presence of linkage and a LOD score greater than 3.0 is considered evidence for linkage. A LOD score of +3 indicates 1000 to 1 odds that the linkage being observed did not occur by chance.
- Transgene or “chimeric gene” refers to a genetic locus comprising a DNA sequence, such as a recombinant gene, which has been introduced into the genome of a plant by transformation, such as Agrobacterium mediated transformation.
- a plant comprising a transgene stably integrated into its genome is referred to as "transgenic plant”.
- isolated nucleic acid sequence or “isolated DNA” refers to a nucleic acid sequence which is no longer in the natural environment from which it was isolated, e.g. the nucleic acid sequence in a bacterial host cell or in the plant nuclear or plastid genome.
- sequence it is understood that the molecule having such a sequence is referred to, e.g. the nucleic acid molecule.
- a "host cell” or a “recombinant host cell” or “transformed cell” are terms referring to a new individual cell (or organism) arising as a result of at least one nucleic acid molecule, having been introduced into said cell.
- the host cell is preferably a plant cell or a bacterial cell.
- the host cell may contain the nucleic acid as an extra-chromosomally (episomal) replicating molecule, or comprises the nucleic acid integrated in the nuclear or plastid genome of the host cell, or as introduced chromosome, e.g. minichromosome.
- sequence similarity or identity may be determined by searching against databases such as FASTA, BLAST, etc., but hits should be retrieved and aligned pairwise to compare sequence identity.
- nucleic acid sequence e.g. DNA or genomic DNA
- nucleic acid sequence having "substantial sequence identity to" a reference sequence or having a sequence identity of at least 80%, e.g. at least 85%, 90%, 92%, 95%, 98%, 99%, 99.2%, 99.5%, 99.9% nucleic acid sequence identity to a reference sequence
- said nucleotide sequence is considered substantially identical to the given nucleotide sequence and can be identified using stringent hybridisation conditions.
- the nucleic acid sequence comprises one or more mutations compared to the given nucleotide sequence but still can be identified using stringent hybridisation conditions.
- Stringent hybridisation conditions can be used to identify nucleotide sequences, which are substantially identical to a given nucleotide sequence. Stringent conditions are sequence dependent and will be different in different circumstances. Generally, stringent conditions are selected to be about 5°C lower than the thermal melting point (Tm) for the specific sequences at a defined ionic strength and pH. The Tm is the temperature (under defined ionic strength and pH) at which 50%> of the target sequence hybridises to a perfectly matched probe. Typically stringent conditions will be chosen in which the salt concentration is about 0.02 molar at pH 7 and the temperature is at least 60°C. Lowering the salt concentration and/or increasing the temperature increases stringency.
- Tm thermal melting point
- Stringent conditions for RNA- DNA hybridisations are for example those which include at least one wash in 0.2X SSC at 63°C for 20min, or equivalent conditions.
- Stringent conditions for DNA- DNA hybridisation are for example those which include at least one wash (usually 2) in 0.2X SSC at a temperature of at least 50°C, usually about 55°C, for 20 min, or equivalent conditions. See also Sambrook et al. (1989) and Sambrook and Russell (2001).
- Ml generation or “Ml plants” in context with the present invention shall refer to the first generation that is produced directly from the mutagenic treatment.
- a plant grown from seeds treated with a mutagen e.g. is a representative of an Ml generation.
- M2 generation or “M2 plant” shall refer herein to the generation obtained from self-pollination of the Ml generation.
- a plant grown from seeds obtained from a self-pollinated Ml plant represents a M2 plant.
- M3, M4, etc. refers to further generations obtained after self-pollination.
- Allelism test refers to a genetic test whereby it can be tested whether a phenotype, e.g. facultative parthenocarpy, seen in two plant lines or varieties are determined by the same gene or locus or by different genes or loci. For example, the plants to be tested are crossed with each other (preferably after selling to ensure they are homozygous), the segregation of the phenotypes amongst the Fl or further selling or backcross progeny is determined. The ratio of segregation indicates if the genes or loci are allelic or if they are different.
- a phenotype e.g. facultative parthenocarpy
- “Fine-mapping” refers to methods by which the position of a gene can be determined more accurately (narrowed down). For example a large population segregating for the trait can be analysed for segregation of the trait and the DNA markers, e.g. SNP1 to SNP24, and plants comprising recombination events in the region between SNP1 and SNP24 can be selected, in order to determine between which pair of SNP markers the gene is located. One can also search for additional markers between the most linked pair of marker to narrow down the interval in which the gene is located.
- DNA markers e.g. SNP1 to SNP24
- mRNA coding sequence shall have the common meaning herein.
- An mRNA coding sequence corresponds to the respective DNA coding (cDNA) sequence of a gene/allele apart from that thymine (T) is replaced by uracil (U).
- a “mutation" in a nucleic acid molecule is a change of one or more nucleotides compared to the corresponding wild type sequence, e.g. by replacement, deletion or insertion of one or more nucleotides. Examples of such a mutation are point mutation, nonsense mutation, missense mutation, splice-site mutation, frame shift mutation or a mutation in a regulatory sequence.
- nucleic acid molecule shall have the common understanding in the art. It is composed of nucleotides comprising either of the sugars deoxyribose (DNA) or ribose (RNA).
- a “point mutation” is the replacement of a single nucleotide, or the insertion or deletion of a single nucleotide.
- a "nonsense mutation” is a (point) mutation in a nucleic acid sequence encoding a protein, whereby a codon in a nucleic acid molecule is changed into a stop codon. This results in a pre-mature stop codon being present in the mRNA and results in translation of a truncated protein.
- a truncated protein may have decreased function or loss of function.
- a “missense or non-synonymous mutation” is a (point) mutation in a nucleic acid sequence encoding a protein, whereby a codon is changed to code for a different amino acid. The resulting protein may have decreased function or loss of function.
- a "splice-site mutation” is a mutation in a nucleic acid sequence encoding a protein, whereby RNA splicing of the pre-mRNA is changed, resulting in an mRNA having a different nucleotide sequence and a protein having a different amino acid sequence than the wild type.
- the resulting protein may have decreased function or loss of function.
- a "frame shift mutation” is a mutation in a nucleic acid sequence encoding a protein by which the reading frame of the mRNA is changed, resulting in a different amino acid sequence.
- the resulting protein may have decreased function or loss of function.
- a “deletion” in context of the invention shall mean that anywhere in a given nucleic acid sequence at least one nucleotide is missing compared to the nucleic sequence of the corresponding wild type sequence or anywhere in a given amino acid sequence at least one amino acid is missing compared to the amino acid sequence of the corresponding (wild type) sequence.
- a "truncation” shall be understood to mean that at least one nucleotide at either the 3'-end or the 5'-end of the nucleotide sequence is missing compared to the nucleic sequence of the corresponding wild type sequence or that at least one amino acid at either the N-terminus or the C-terminus of the protein is missing compared to the amino acid sequence of the corresponding wild type protein, whereby in a 3 '- end or C-terminal truncation at least the first nucleotide at the 5'-end or the first amino acid at the N- terminus, respectively, is still present and in a 5'-end or N-terminal truncation at least the last nucleotide at the 3'-end or the last amino acid at the C-terminus, respectively, is still present.
- the 5'-end is determined by the ATG codon used as start codon in translation of a corresponding wild type nucleic acid sequence.
- Replacement shall mean that at least one nucleotide in a nucleic acid sequence or one amino acid in a protein sequence is different compared to the corresponding wild type nucleic acid sequence or the corresponding wild type amino acid sequence, respectively, due to an exchange of a nucleotide in the coding sequence of the respective protein.
- “Insertion” shall mean that the nucleic acid sequence or the amino acid sequence of a protein comprises at least one additional nucleotide or amino acid compared to the corresponding wild type nucleic acid sequence or the corresponding wild type amino acid sequence, respectively.
- Pre-mature stop codon in context with the present invention means that a stop codon is present in a coding sequence (cds) which is closer to the start codon at the 5'-end compared to the stop codon of a corresponding wild type coding sequence.
- a "mutation in a regulatory sequence" e.g. in a promoter or enhancer of a gene, is a change of one or more nucleotides compared to the wild type sequence, e.g. by replacement, deletion or insertion of one or more nucleotides, leading for example to decreased or no mRNA transcript of the gene being made.
- a “mutation in a protein” is a change of one or more amino acid residues compared to the wild type sequence, e.g. by replacement, deletion, truncation or insertion of one or more amino acid residues.
- “Mutant protein” is herein a protein comprising one or more mutations in the nucleic acid sequence encoding the protein, whereby the mutation results in (the mutant nucleic acid molecule encoding) a "reduced-function” or “loss-of-function” protein, as e.g. measurable in vivo, e.g. by the phenotype conferred by the mutant allele.
- “decreased activity” of a protein shall mean a decrease in activity of a WOPl protein when compared to a corresponding wild type plant cell or a corresponding wild type plant.
- Decrease shall in one aspect comprise an entire knock-out or knock-down of gene expression, or the production of a loss-of-function or of a reduced-function WOPl protein, e.g. a mutant WOPl protein may have lost function or decreased function compared to the wild type, functional WOPl protein.
- a decrease in activity can be a decrease in the expression of a gene encoding a WOPl protein (also referred to as knock-down), or a knock-out of the expression of a gene encoding a WOPl protein and/or a decrease in the quantity of a WOPl protein in the cells, or a reduced- function or loss-of-function in the activity of a WOPl protein in the cells.
- wild type plant or wild type plant cell is a plant or plant cell comprising fully functional WOPl genes, encoding a fully functional WOPl proteins (also referred to as wild type WOPl protein), e.g. regarding watermelon plants or plant cells a diploid watermelon plant producing the protein of SEQ ID NO: 32 (or a protein comprising at least 95% sequence identity to SEQ ID NO: 32) and producing fruits only after pollination.
- melon plants or cells a diploid melon plant producing the protein of SEQ ID NO: 34 (or a protein comprising at least 95%> sequence identity to SEQ ID NO: 34) or regarding cucumber plants or cells a diploid cucumber plant producing the protein of SEQ ID NO: 33 (or a protein comprising at least 95% sequence identity to SEQ ID NO: 34).
- knock-out or “entire knock-out” shall be understood that expression of the respective gene is not detectable anymore.
- Loss-of-function or “reduced-function” or “decreased function” shall mean in context of the present invention that the protein, although possibly present in amounts equal or similar to a corresponding wild type protein, does not evoke its normal effect anymore, i.e. for mutant alleles encoding such a protein when present in homozygous form in a diploid plant, the plant produces seedless fruits in the absence of pollination and seeded fruits in the presence of pollination.
- Consed domain refer to conserved protein domains, such as the "myb-like DNA-binding domain, SHAQKYF class", e.g. of SEQ ID NO: 35, or the "SHAQKYF domain” of amino acids 47 to 54 of SEQ ID NO: 35.
- conserved domains can e.g. be found in the conserveed Domain Database of the NCBI (world wide web at ncbi.nlm.nih.gov/cdd).
- Figure 1 1 A and 1C show seedless fruits of a diploid, parthenocarpic watermelon plant of the invention, homozygous for the wopl allele as e.g. found in NCIMB42533.
- Figure IB shows a female flower of the same plant developing a seedless fruit without pollination.
- Figure 2 schematic (not to scale) diagram of chromosome 4 of cultivated watermelon and the region to which WOP1 was mapped.
- the SNP markers found in between SNP3 and SNP23 are not shown, i.e. SNP4 to SNP22.
- the physical location and distance between the SNPs, as well as the SNP genotype, is shown in Table 1.
- Figure 3 leaf of a facultative parthenocarpic watermelon inbred backcross line homozygous for the mutant wopl allele (as e.g. found in NCIMB42533) (left leaf) and leaf of a wild type watermelon plant (right leaf).
- the modified leaf morphology (left leaf) is also seen in backcross inbred lines heterozygous for the mutant wopl allele.
- a first embodiment of the present invention concerns cultivated watermelon plants, Citrullus lanatus, comprising at least one copy of a mutant allele of a gene conferring parthenocarpy when the mutant allele is in homozygous form, especially facultative parthenocarpy.
- cultivated watermelon plants comprising at least one copy of a mutant allele of a single recessive gene called WOPl .
- the WOPl gene is an endogenous gene of cultivated watermelon, which when mutated and in homozygous form results in parthenocarpy, especially facultative parthenocarpy.
- a segregating population made by crossing the mutant parthenocarp watermelon plant identified by the inventors with an elite watermelon line enabled mapping of the WOPl gene to a region on chromosome 4 between 8.3 Mb (SNPl a) or 11.9 Mb (SNP1) and 21.8 Mb (SNP24) of the chromosome, in particular the WOPl gene was mapped to the region of chromosome 4 starting at nucleotide 14.402.485 (SNP3) and ending at nucleotide 18.942.612 (SNP23) of chromosome 4, see Table 1 below and Figure 2. Further analysis led to the identification of SNP16a comprising a polymorphism in a protein coding sequence.
- mutant parthenocapric watermelon plant SNP16a comprised an Adenine at nucleotide 428 of SEQ ID NO: 30, while the wild type plant comprised a Guanine at nucleotide 428.
- the wild type protein, depicted in SEQ ID NO: 32 comprises a Serine at amino acid 143
- the mutant protein, depicted in SEQ ID NO: 31 comprises an Aspargine at amino acid 143. There were no introns in the sequence, so the genomic DNA and coding DNA (cDNA, and corresponding mRNA) are identical.
- SNP Physical SNP SNP Sequence comprising the SNP (with SNP marker position (in nucleotide in nucleotide in indicated between brackets in bold) name base pairs) on plant plant
- chromosome 4 comprising comprising
- AATT SEQ ID NO: l
- TGT CAACAAAAAGGTGTGCAG GGTAGTGCAACCTGAAGAAGAAAT ACAAACGCATAGACTTCCTGATCCT CAAGTAGA (SEQ ID NO: 2)
- CAACTTCA (SEQ ID NO:8)
- TCTAA SEQ ID NO: 17
- ATAATC [G/T] GATTGATATATATGG AAATTTACGATCATAGAATAATTAT TTTAGGGCCATTTTTTTAATTGACG TTTAA (SEQ ID NO:23)
- SNPl refers herein either to nucleotide 76 of SEQ ID NO: 1, or nucleotide 76 of a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1, and/or, SNPl refers to SEQ ID NO: 1, or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1.
- SNPl refers herein to (nucleotide 76 of) SEQ ID NO: 1, or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1.
- SNPla refers herein to (nucleotide 76 of) SEQ ID NO: 29, or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 29;
- SNPl refers herein (to nucleotide 76) of SEQ ID NO: 1, or (nucleotide 76 of) a sequence comprising at least 95%>, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1 ;
- SNP2 refers (to nucleotide 76 of) SEQ ID NO: 2, or (nucleotide 76 of) a sequence comprising at least 95%>, 96%>, 97%>, 98%> or 99%> sequence identity to SEQ ID NO:2;
- SNP3 refers (to nucleotide 76 of) SEQ ID NO: 3, or (nucleotide 76 of) a sequence comprising at least
- Sequence identity is preferably determined by pairwise alignment of sequences of the same length.
- the WOP1 gene and the copy of the mutant allele is located in the region between 8.3Mb (SNPla) or 11.9 Mb (SNP1) and 21.8 Mb (SNP24), preferably between 14.4 Mb (SNP3) and 18.9 Mb (SNP23) of chromosome 4.
- the WOP1 gene and the copy of the mutant allele is located in the region between 16.5Mb (SNP16) and 16.9Mb (SNP17).
- the WOP1 gene and the copy of the mutant wopl allele is linked to SNP16a or to SEQ ID NO: 30 or a sequence comprising at least 95% sequence identity to SEQ ID NO: 30, preferably to a Adenine at nucleotide 428 of SEQ ID NO: 30.
- the copy of the mutant allele is, in one aspect, located between (nucleotide 76 of) SEQ ID NO: l or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No:l and (nucleotide 76 of) SEQ ID No: 24 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No:24.
- the copy of the mutant allele is, in one aspect, located between (nucleotide 76 of) SEQ ID NO:29 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No:29 and (nucleotide 76 of) SEQ ID NO 24 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No:24.
- the WOP1 gene and the copy of the mutant allele is located in the region between 14.4 Mb (SNP3) and 18.9 Mb (SNP23).
- the copy of the mutant allele is, in another aspect, located between (nucleotide 76 of) SEQ ID NO:3 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No:3 and (nucleotide 81 of) SEQ ID No: 23 or (nucleotide 81 of) a sequence comprising at least 95%, 96%, 97%, 98%) or more sequence identity to SEQ ID No:23.
- the WOP1 gene and the copy of the mutant allele is located in the region between 16.5 Mb (SNP 16) and 16.9 Mb (SNP 17).
- SNP 16 As nucleotide 16.540.678 is SNP 16 herein and nucleotide 16.908.561 is SNP 17 herein, the copy of the mutant allele is, in another aspect, located between (nucleotide 76 of) SEQ ID NO: 16 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No: 16 and (nucleotide 76 of) SEQ ID No: 17 or (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or more sequence identity to SEQ ID No: 17.
- the mutant allele is located in the region between any two SNP markers selected from the group consisting of SNPla to SNP24; or between any two SNP markers selected from the group consisting of SNPl to SNP24; or between any two SNP markers selected from the group consisting of SNP3 to SNP23.
- the mutant wopl allele is found between SNPl (or SNPla) and SNP3, between SNP2 and SNP4, between SNP3 and SNP5, between SNP4 and SNP6, etc. up to between SNP22 and SNP24.
- the mutant wopl allele is found between SNP3 and SNP5, or between SNP4 and SNP6, or between SNP5 and SNP7, or between SNP6 and SNP8, etc. up to between SNP21 and SNP23.
- the mutant wopl allele is found between SNP 16 and SNP 17. Fine-mapping and/or sequencing can be done do determine between which pair of SNP markers the mutant allele is located and/or to identify the gene itself.
- the WOP1 gene is the gene encoding the protein of SEQ ID NO: 32, herein referred to as the WOP1 protein.
- One mutant wopl allele according to the invention is the mutant allele comprising the nucleotide sequence of SEQ ID NO: 30, encoding the mutant WOP1 protein of SEQ ID NO: 31, but other mutant wopl alleles are also encompassed herein, as described elsewhere herein.
- the mutant wopl allele is linked to (preferably closely linked to) at least one molecular marker, preferably a SNP marker (or sequence comprising the SNP marker, or a sequence comprising at least 90%, 95%, 96%, 97%, 98% or 99% sequence identity to the sequence comprising the SNP marker) selected from the group consisting of SNPla, SNP1, SNP2, SNP3, SNP4, SNP5, SNP6, SNP7, SNP 8, SNP9, SNP10, SNP11, SNP 12, SNP13, SNP 14, SNP15, SNP 16, SNP16a, SNP 17, SNP18, SNP 19, SNP20, SNP21, SNP22, SNP23 and SNP24.
- a SNP marker or sequence comprising the SNP marker, or a sequence comprising at least 90%, 95%, 96%, 97%, 98% or 99% sequence identity to the sequence comprising the SNP marker
- the wopl allele is linked to, preferably closely linked to, at least one marker selected from the group consisting of SNP3, SNP4, SNP5, SNP6, SNP7, SNP8, SNP9, SNP10, SNP11, SNP 12, SNP13, SNP 14, SNP 15, SNP 16, SNP16a, SNP 17, SNP 18, SNP 19, SNP20, SNP21, SNP22 and SNP23.
- the mutant wopl allele is linked to SNP 16, SNP16a and/or SNP 17, preferably to at least SNP16a, e.g. to an Adenine at nucleotide 428 of SEQ ID NO: 30.
- the mutant allele of the WOP1 gene is in one aspect the mutant allele as found in seeds deposited under accession number NCIMB42533 or progeny thereof.
- the mutant allele comprises a mutation in the genomic DNA (identical to the cDNA and mRNA, whereby in the mRNA 'Thymine' is replaced by 'Uracil') of SEQ ID NO: 30, resulting in the expression of a mutant WOP1 protein (SEQ ID NO: 31).
- the mutant WOP1 protein comprises a single amino acid replacement of Serine 143 (replaced by Asparagine). This amino acid replacement is in the conserved domain referred to as myb-like DNA binding domain SHAQKYF class.
- amino acid substitution is in the C-terminal of that conserved domain, in the SHAQKYF domain.
- the myb-like DNA binding domain SHAQKYF class is highly relevant for the three dimensional structure of the protein and comprises several alpha helices.
- the amino acid substitution in this conserved domain leads to a reduced function of the protein, possibly even a loss-of- function, compared to the wild type WOP1 protein of SEQ ID NO: 32.
- mutant WOP1 allele as found in the deposited seeds is one aspect of the invention.
- mutant alleles of the WOP1 gene, causing facultative parthenocarpy when in homozygous form are embodiments of the invention.
- Such different mutant wopl alleles can be generated by the skilled person without undue burden.
- the skilled person can, for example, generate other mutants in the WOP1 gene and determine whether they equally result in facultative parthenocarpy when in homozygous form in a diploid watermelon plant.
- the WOP1 gene in watermelon was identified to be a gene encoding a protein of SEQ ID NO: 32, which is a small protein comprising the conserved "myb-like DNA binding SHAQKYF class" domain from amino acid 97 to amino acid 150 of SEQ ID NO: 32.
- the conserved domain is also depicted in SEQ ID NO: 35.
- the skilled person can generate watermelon plants comprising mutants in the WOP1 gene by various methods, e.g. mutagenesis, TILLING or CRISPR-Cas or other methods known in the art. Especially with targeted gene modification technologies such as Crispr-Cas, TALENS and others, targeted mutations can be made by the person skilled in the art. He can then confirm the phenotype of a plant homozygous for the mutant wopl allele, i.e. being facultative parthenocarpic, optionally in comparison to the phenotype of plants accession number NCIMB42533 or progeny thereof.
- the skilled person is not limited to the specific WOP1 mutant generated by the inventors and of which the mutant allele is present in the deposited seeds, but the skilled person can equally generate other mutations in the wopl allele of watermelon, and also of cucumber and melon, and thereby generate other mutants which lead to facultative parthenocarpy when in homozygous form.
- Various mutations can be generated and tested for the resulting phenotype, for example the regulatory elements can be mutated to reduce expression (knock-down) or eliminate expression (knock-out) of the allele and thus reduce or eliminate the amount of WOP1 protein present in the cell or plant.
- mutations which lead to reduced function or loss-of- function of the WOP1 protein can be generated, i.e.
- the WOP1 protein comprises a large conserved domain, the "myb-like DNA binding SHAQKYF class domain", encompassing a smaller conserved domain, the SHAQKYF domain", it is in one aspect encompassed that one or more amino acids are replaced, deleted or inserted in either of these domains, as such mutations will likely reduced the protein function or result in a loss of function.
- Whether the mutation results in the expected phenotype can then be tested by generating plants homozygous for the mutation through selfing and growing the plant line with and without pollination of the flowers to see if fruits develop in a facultative parthenocarpic way.
- the skilled person can carry out a method for production of a facultative parthenocarpic cultivated watermelon plant comprising the steps of: a) introducing mutations in a population of watermelon plants, especially cultivated watermelon plants or providing a population of mutated plants or progeny thereof; b) selecting a plant producing seedless fruits without pollination of the female flowers and producing a seeded fruit after pollination of the female flowers; c) optionally determining if the plant selected under b) comprises a mutant allele of a WOP1 gene; and d) optionally growing the plants obtained under c).
- Steps b) and c) can also be switched, so that step b) is selecting a plant comprising a mutant allele of a WOP1 gene and step c) is determining if the plant (or a progeny thereof produced by selfing) producing seedless fruits without pollination of the female flowers and producing a seeded fruit after pollination of the female flowers.
- Step a) can be carried out by e.g. mutagenizing seeds of one or more lines or varieties of watermelon, for example by treatment with mutagenizing agents such as chemical mutagens, e.g. EMS (ethyl methane sulphonate), or irradiation with UV radiation, X-rays or gamma rays or the like.
- the population may for example be a TILLING population.
- the mutagnized plant population is selfed at least once (e.g. to produce an M2 generation, or M3, M4, etc.) prior to carrying out step b).
- step b) relating to phenotyping, plants are preferably grown in an insect proof environment to avoid the presence of pollinators.
- Regular visual inspection of female flowers, fruit setting of those flowers without pollination and visual inspection of the mature fruits can be carried out to identify mutants which producing seedless fruits without pollination of the female flowers.
- Such plants, or selfing progeny thereof can be tested for the presence of the mutant WOP1 gene by pollinating the female flowers to see if the fruits are seeded after pollination, genotyping the plants for mutations in the WOP1 gene and encoded protein, or expression of the WOP1 gene, or genotyping the plant for one or more or all of SNP1 (or SNPla) to SNP24, allelism tests by e.g.
- step b) is the selection of plants comprising a mutant allele of the WOP1 gene
- the skilled person can also use various methods for detecting the DNA, mRNA or protein of the WOP1 gene in order to identify a plant comprising a mutant wopl allele.
- the genomic coding DNA of the wild type WOP1 gene, encoding a functional WOP1 protein is the DNA of SEQ ID NO: 30, except that the Adenine at nucleotide 428 is a Guanine.
- the promoter is upstream of this sequence and can e.g. be retrieved by sequencing or from the watermelon genome database.
- the mutant allele of the WOP1 gene is a mutant allele resulting in reduced expression or no expression of the WOP1 gene or is a mutant allele resulting in one or more amino acids of the encoded WOP1 protein being replaced, inserted or deleted, compared to the wild type WOP1 protein.
- the mutant allele of the WOP1 gene is obtainable from seeds deposited under accession number NCIMB42533 or progeny thereof, e.g. by crossing a plant comprising one or two copies of the mutant wopl allele with another cultivated watermelon plant.
- NCIMB42533 the SNP genotype of one or more or all of the SNP markers selected from SNP1 (or SNPla) to SNP24 (or SNP3 to 23) can be determined.
- the genotype of SNP16a can be determined and used to select progeny plants comprising an Adenine at nucleotide 428 of SEQ ID NO: 30 and thus comprising the mutant wopl allele.
- the diploid plant heterozygous for wopl i.e. wopl /WOP 1
- will be heterozygous for the SNP markers e.g. will have the genotype 'AG' for SNP1 (i.e.
- the plant comprises one chromosome 4 having an Adenine, A, at nucleotide 76 of SEQ ID NO: 1 or at nucleotide 76 of a sequence comprising at least 95%, 96%, 97%>, 98%> or more sequence identity to SEQ ID NO: l and a second chromosome 4 having a Guanine, G, at nucleotide 76 of SEQ ID NO: 1 or at nucleotide 76 of a sequence comprising at least 95%>, 96%>, 97%>, 98%> or more sequence identity to SEQ ID NO:l), while a plant homozygous for wopl (i.e.
- wopl/wopl will have the genotype 'AA' for SNP1 (i.e. the plant comprises two chromosomes 4 which both have an Adenine, A, at nucleotide 76 of SEQ ID NO: 1 or at nucleotide 76 of a sequence comprising at least 95%>, 96%>, 97%>, 98%> or more sequence identity to SEQ ID NO: l).
- the diploid plant heterozygous for wopl i.e. wopl/WOPl
- will be heterozygous for the SNP16a i.e. will have the genotype 'AG' for SNP 16a (i.e.
- the plant comprises one chromosome 4 having an Adenine, A, at nucleotide 428 of SEQ ID NO: 30 or at nucleotide 428 of a sequence comprising at least 95%), 96%o, 97%o, 98%) or more sequence identity to SEQ ID NO:30 and a second chromosome 4 having a Guanine, G, at nucleotide 428 of SEQ ID NO: 30 or at nucleotide 428 of a sequence comprising at least 95%), 96%>, 97%>, 98%> or more sequence identity to SEQ ID NO:30), while a plant homozygous for wopl (i.e.
- wopl/wopl will have the genotype 'AA' for SNP16a (i.e. the plant comprises two chromosomes 4 which both have an Adenine, A, at nucleotide 428 of SEQ ID NO:30 or at nucleotide 428 of a sequence comprising at least 95%>, 96%>, 97%>, 98%> or more sequence identity to SEQ ID NO: 30).
- SNP genotype of triploids homozygous for wopl will be 'AAA' for SNP1 and/or for SNP 16a, and distinguishable from the other genotypes 'AAG', 'AGG' and 'GGG'.
- SNP16a is linked to the mutant wopl allele and plants can be selected comprising an Adenine for SNP16a.
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form.
- WOPl gene is located on chromosome 4 of the cultivated watermelon genome. The whole genome of watermelon has been sequenced, see Guo et al. 2013, Nature Genetics, page 51-60 and the sequence database is available for all chromosomes.
- Table 1 above the SNP markers SNP1 (and SNPla) to SNP24 are shown, including their physical position on chromosome 4.
- the gene is located in a region starting at base pair 11.906.147 (SNP1) and ending at base pair 21.897.585 (SNP24) of chromosome 4.
- the gene is located in a region starting at base pair 8.385.759 (SNPla) and ending at base pair 21.897.585 (SNP24) of chromosome 4.
- the gene is located in a region starting at base pair 16.540.678 (SNP16) and ending at base pair 16.908.561 (SNP 17).
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located in a region starting at (nucleotide 76 of) SEQ ID NO: 1 (SNP1), or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1 (SNP1), and ending at (nucleotide 76 of) SEQ ID NO: 24 (SNP24) or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 24 (SNP24).
- the gene is located in a region starting at (nucleotide 76 of) SEQ ID NO: 29 (SNPla), or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 29 (SNPla), and ending at (nucleotide 76 of) SEQ ID NO: 24 (SNP24) or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98%o or 99%) sequence identity to SEQ ID NO: 24 (SNP24).
- the gene is located in a region starting at (nucleotide 76 of) SEQ ID NO: 16 (SNP16), or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 16 (SNP 16), and ending at (nucleotide 76 of) SEQ ID NO: 17 (SNP 17) or at (nucleotide 76 of) a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 17 (SNP 17).
- the mutant allele is a mutant allele of the gene which encodes the WOPl protein of SEQ ID NO: 32 or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32 (wild type functional protein), whereby the mutant allele has a reduced expression or no expression, or whereby the mutant allele encodes a mutant WOPl protein comprising one or more amino acids replaced, inserted or deleted compared to the wild type protein.
- the one or more amino acid replacements, insertions or deletions comprise or consist of the replacement, insertion or deletion of one or more amino acids in one or both of the conserved domains.
- the mutant protein has a reduced-function or loss-of-function compared to the wild type protein (and thus compared to a wild type plant comprising the wild type WOP1 gene), preferably the plant cell or plant comprising the mutant allele in homozygous form is facultative parthenocarpic.
- SNP nucleotide or SNP genotype at a specific nucleotide position e.g. at nucleotide 76 of SEQ ID NO: 1
- "or at nucleotide 76 of a sequence comprising at least 95%, 96%, 97%, 98%) or 99% sequence identity to the SEQ ID NO” this means that the SNP nucleotide or SNP genotype is present in a variant sequence at a nucleotide corresponding to the same nucleotide (e.g. corresponding to nucleotide 76 of SEQ ID NO: 1) in the variant sequence, i.e.
- variant sequence in a sequence comprising at least 95%, 96%), 97%), 98%o or 99% sequence identity to the mentioned SEQ ID NO. It may for example be that the variant sequence is one or a few nucleotides shorter, but when one pairwise aligns the variant sequence with the mentioned SEQ ID NO, one can see which nucleotide of the variant sequence corresponds to the same nucleotide. In the variant sequence this may for example be nucleotide number 75 or 77 of that variant sequence which corresponds to nucleotide 76 of the mentioned sequence.
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOP1 , said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located between SEQ ID NO: 1 (comprising SNP1), or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1 , and SEQ ID NO: 24 (comprising SNP24) or a sequence comprising at least 95%, 96%, 97%), 98%o or 99% sequence identity to SEQ ID NO: 24.
- SEQ ID NO: 1 comprising SNP1
- SEQ ID NO: 24 comprising SNP24
- said gene is located between SEQ ID NO: 29 (comprising SNPl a), or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 29, and SEQ ID NO: 24 (comprising SNP24) or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 24.
- the gene is located in a region starting at base pair 14.402.485 (SNP3) and ending at base pair 18.942.612 (SNP23) of chromosome 4.
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOP1 , said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located in a region starting at nucleotide 76 of SEQ ID NO: 3 (SNP3), or at nucleotide 76 of a sequence comprising at least 95%, 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 3 (SNP3), and ending at nucleotide 81 of SEQ ID NO: 23 (SNP23) or at nucleotide 81 of a sequence comprising at least 95%, 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 23 (SNP23).
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located between SEQ ID NO: 3 (comprising SNP3), or a sequence comprising at least 95% 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 3, and SEQ ID NO: 23 (comprising SNP23) or a sequence comprising at least 95%, 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 23.
- a cultivated watermelon plant comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located between SEQ ID NO: 16 (comprising SNP16), or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 16, and SEQ ID NO: 17 (comprising SNP17) or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 17.
- the WOPl gene is the gene encoding a protein of SEQ ID NO: 32 or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32.
- the mutant allele is a mutation in an endogenous gene of cultivated watermelon. The existence of a gene conferring facultative parthenocarpy and the location of the gene to the defined region on chromosome 4 enables the skilled person to generate other de novo mutants in the gene, i.e. in other cultivated watermelon lines or varieties.
- SNP genotype may be different in different genetic backgrounds and which is why SEQ ID NO: 1 to SEQ ID NO: 24 (and SEQ ID NO: 29) may not be 100% identical in other genetic backgrounds to the sequences provided herein, but may comprise at least 95%, 96%, 97%, 98% or 99% sequence identity to the sequences provided as SEQ ID NO:l to SEQ ID NO: 24 (and SEQ ID NO: 29). Nonetheless, the skilled person can, without undue burden, generate plants according to the invention, e.g. by carrying out a method for identification of mutants in a mutant population, based e.g.
- the WOPl gene has been identified to be the gene encoding a protein of SEQ ID NO: 32 (wild type protein) in normal, non-parthenocarpic watermelon plants, other mutants than the one generated by the inventors (encoding the mutant protein of SEQ ID NO: 31) can be generated de novo.
- the wild type WOPl protein need not be 100% identical to the protein of SEQ ID NO: 32, but may have less sequence identity, e.g.
- the conserved myb- like DNA binding SHAQKYF-class domain is however 100% identical to that of SEQ ID NO: 32, i.e. has the sequence of SEQ ID NO: 35, in such wild type variant proteins, so that WOP1 genes are encompassed comprising mutants in genes encoding WOP1 proteins which proteins comprise at least 95% sequence identity to SEQ ID NO: 32 when aligned over the entire length, and such proteins comprise the conserved myb-like DNA binding SHAQKYF-class domain of SEQ ID NO: 35.
- the plant according to the invention is a cultivated watermelon plant or a part thereof, comprising at least one copy of a mutant allele of a gene name WOP1, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is linked a nucleotide sequence selected from the group consisting of SEQ ID NO: 1 or a sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 1 ; SEQ ID NO: 2 or a nucleotide sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 2; SEQ ID NO: 3 or a nucleotide sequence comprising at least 95%, 96%, 97%, 98% or 99% sequence identity to SEQ ID NO: 3; SEQ ID NO: 4 or a nucleotide sequence comprising at least 95%, 96%, 97%, 98% or 99%o sequence identity
- the mutant wopl allele is linked to any one of the above sequences, or to the SNP present in those sequences, at a physical distance of 2.5 Mb or less, such as 2.0 Mb or less, 1.5Mb or less, 1.0 Mb or less, 0.8 Mb or less, 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less.
- 2.5 Mb or less such as 2.0 Mb or less, 1.5Mb or less, 1.0 Mb or less, 0.8 Mb or less, 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less.
- the mutant wopl allele is linked to any one of the above sequences, or to the SNP present in those sequences, at a physical distance of 0.5 Mb or less, 0.4 Mb or less, 0.3Mb or less, 0.2 Mb or less, 0.1 Mb or less, 74kb, 50kb, 20kb, lOkb, 5kb, 2kb, lkb or less.
- the mutant allele is located in the region of chromosome 4 starting at SNPl (or at SNP la) and ending at SNP24, preferably starting at SNP3 and ending at SNP23, as described elsewhere.
- the linkage can be determined using mapping e.g. fine mapping.
- Linkage can also be expressed in centiMorgans (cM), so in one aspect the wopl allele is linked to any one of the above markers within a genetic distance of 5 cM or less, e.g. 4 cM, 3 cM, 2 cM, 1 cM or less.
- the plant according to the invention is a cultivated watermelon plant or a part thereof, comprising at least one copy of a mutant allele of a gene name WOP1, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located between a pair of SNP markers, or between a pair of sequences comprising the markers, selected from the group consisting of SNPla (or SEQ ID NO: 29) and SNP3 (or SEQ ID NO: 3); SNPl (or SEQ ID NO: 1) and SNP3 (or SEQ ID NO:3); SNP2 (or SEQ ID NO: 2) and SNP4 (or SEQ ID NO: 4); SNP3 (or SEQ ID NO: 3) and SNP5 (or SEQ ID NO: 5); SNP4 (or SEQ ID NO: 4) and SNP6 (or SEQ ID NO: 6); SNP5 (or SEQ ID NO: 5) and SNP7 (or SEQ ID NO:
- this includes the SNP markers in variant genomic sequences, such as a sequence comprising at least 95% sequence identity to the SEQ ID NO comprising the SNP and, likewise, when referring to sequences this also includes variant genomic sequences, such as a sequence comprising at least 95% sequence identity to the SEQ ID NO.
- the plant according to the invention is a cultivated watermelon plant or a part thereof, comprising at least one copy of a mutant allele of a gene name WOPl, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, wherein said gene is located between a pair of SNP markers, or between a pair of sequences comprising the markers, selected from the group consisting of SNP16 (or SEQ ID NO: 16) and SNP 17 (or SEQ ID NO: 17).
- the mutant wopl allele is the allele as present in, and as obtainable from, plants grown from seeds deposited under accession number NCIMB42533, or progeny thereof, e.g. Fl, F2, F3 or further selling progeny or BC1, BC2, BC3, etc., or DH progeny, or tetraploid or triploids (or other polyploids) made using the allele present in NCIMB42533.
- progeny thereof e.g. Fl, F2, F3 or further selling progeny or BC1, BC2, BC3, etc.
- DH progeny or tetraploid or triploids (or other polyploids) made using the allele present in NCIMB42533.
- the wopl allele is in one aspect detectable by SNP genotyping using one or more or all of SNPl (or SNPla) to SNP24, preferably one or more or all of SNP3 to SNP23, or a subset of these SNPs linked to wopl.
- the subset of SNP markers linked to the mutant wopl allele is one, or more or all of SNPla, SNPl, SNP2, SNP 12, SNP 16, SNP 16a, SNP19, SNP22 and SNP23.
- SNP16a is linked to the mutant gene, as it is in fact present in the protein coding sequence of the mutant wop 1 allele.
- the SNP nucleotide of SNPl (or SNPla) to SNP24 linked to the mutant wopl allele as found in seeds deposited under NCIMB42533 is given in Table 1, in column 3, and the SNP nucleotide of SNPl (or SNPla) to SNP24 linked to the wild type WOPl allele as found in seeds deposited under NCIMB42533 is given in Table 1, column 4.
- the genotype detected confirms whether the mutant wopl allele and/or the wild type WOPl allele is present, and how many copies are present of each. Especially genotyping for SNP 16a is sufficient, as this SNP is in the coding sequence of the allele.
- the plant or plant part according to the invention comprises at least one (but optionally 2 in a homozygous diploid, 3 in a triploid or 4 in a tetraploid or even more in other polyploids) 'A' nucleotide for SNPla, and/or at least one 'A' nucleotide for SNPl, and/or at least one 'T' nucleotide for SNP2, and/or at least one 'C nucleotide for SNP3, and/or at least one 'C nucleotide for SNP4, and/or at least one 'A' nucleotide for SNP5, and/or at least one 'C nucleotide for SNP6, and/or at least one 'T' nucleotide for SNP7, and/or at least one 'G' nucleotide for SNP8, and/or at least one 'C nucleotide for SNP9, and/or at least one 'A' nucle
- the plant or plant part according to the invention comprises at least one (but optionally 2 in a homozygous diploid, 3 in a triploid or 4 in a tetraploid or even more in other polyploids) 'A' nucleotide for SNP16a.
- the plant or plant part according to the invention comprises at least one (but optionally 2 in a homozygous diploid, 3 in a triploid or 4 in a tetraploid or even more in other polyploids) 'C nucleotide for SNP3, and/or at least one 'C nucleotide for SNP4, and/or at least one 'A' nucleotide for SNP5, and/or at least one 'C nucleotide for SNP6, and/or at least one ' nucleotide for SNP7, and/or at least one 'G' nucleotide for SNP8, and/or at least one 'C nucleotide for SNP9, and/or at least one 'A' nucleotide for SNP10, and/or at least one 'G' nucleotide for SNP11, and/or at least one 'A' nucleotide for SNP12, and/or at least one 'G' nucleo
- the plant or plant part according to the invention comprises at least one (but optionally 2 in a homozygous diploid, 3 in a triploid or 4 in a tetraploid or even more in other polyploids) 'A' nucleotide for SNP la, and/or at least one 'A' nucleotide for SNP1, and/or at least one ' nucleotide for SNP2, and/or at least one 'A' nucleotide for SNP12, and/or at least one 'A' nucleotide for SNP16, and/or at least one 'A' nucleotide for SNP16a, and/or at least one 'G' nucleotide for SNP19, and/or at least one 'G' nucleotide for SNP22, and/or at least one 'G' nucleotide for SNP23.
- the plant or plant part according to the invention comprises at least one (but optionally 2 in a homozygous diploid, 3 in a triploid or 4 in a tetraploid or even more in other polyploids) 'A' nucleotide for SNP16a, which is the mutation in the coding sequence of the mutant wopl allele present in the deposited seeds.
- SNP markers described herein may be detected according to standard method.
- SNP markers can easily be detected using a KASP-assay (see world wide web at kpbioscience.co.uk) or other SNP genotyping assays.
- KASP-assay see world wide web at kpbioscience.co.uk
- For developing a KASP-assay for example 70 base pairs upstream and 70 base pairs downstream of the SNP can be selected and two allele-specific forward primers and one allele specific reverse primer can be designed. See e.g. Allen et al. 2011, Plant Biotechnology J. 9, 1086-1099, especially p097-1098 for KASP-assay method.
- the SNP markers and the presence/absence of the SNP nucleotide associated with the wopl allele is determined using a KASP assay, but equally other genotyping assays can be used.
- a TaqMan SNP genotyping assay e.g., a High Resolution Melting (HRM) assay, SNP- genotyping arrays (e.g. Fluidigm, Illumina, etc.) or DNA sequencing may equally be used.
- HRM High Resolution Melting
- Genotyping of diploid plants or plant parts can distinguish SNP genotypes, e.g. plants or parts comprising AA for SNPl can be distinguished from plants or parts comprising AG for SNPl in their genome.
- Genotyping of tetraploid plants or plant parts can be done in the same way as for diploids, using for example a KASP-assay to distinguish SNP genotypes, e.g. plants or parts comprising AAAA for SNPl can be distinguished from plants or parts comprising other genotypes for SNPl, e.g. AGGG, AAGG, etc. in their genome. The same applies for triploids.
- genotyping of triploid plants or plant parts can be done in the same way, using for example a KASP-assay to distinguish SNP genotypes, e.g. plants or parts comprising AAA for SNPl can be distinguished from plants or parts comprising AAG, AGG, GGG for SNPl in their genome.
- KASP-assay to distinguish SNP genotypes, e.g. plants or parts comprising AAA for SNPl can be distinguished from plants or parts comprising AAG, AGG, GGG for SNPl in their genome.
- AAG AGG
- GGG GGG
- the skilled person can also derive the mutant wopl gene from seeds deposited under NCIMB42533 without deriving any of the SNP nucleotides/genotypes indicated in Table 1, column 3 from the deposited seeds. This can for example be done by finding other markers close to the wopl allele and using such markers to select for the presence of the wopl allele. In that way the mutant allele can be crossed into any different genetic background without transferring all the SNP markers of the deposited seeds, i.e. without transferring the chromosome 4 region around the wopl allele, e.g. only SNP 16a may be transferred to progeny. Similarly, phenotypic selection can be used to cross the mutant wopl allele into any different genetic background than the genetic background of NCIMB42533.
- a cultivated watermelon plant or plant part comprising at least one copy of the wopl allele in its genome, said allele conferring facultative parthenocarpy when it is in homozygous form, wherein said allele is obtainable (derivable; the allele is the allele as present in) seeds deposited under accession number NCIMB42533, e.g. by crossing plants grown from the seeds comprising the wopl allele (preferably in homozygous form) with another watermelon plant, such as a breeding line or variety, e.g. comprising only the wild type WOPl allele.
- the Fl will then comprise wopl in heterozygous form and can be e.g.
- the same mutant allele as present in the deposited seed can be generated and/or selected for by the skilled person, e.g. in a different watermelon background, optionally even in a variant of the WOPl gene.
- the mutant allele may comprise a replacement of the serine of amino acid 143 in a protein which comprises at least 95%, 96%, 97%> or 98%> sequence identity to SEQ ID NO: 32.
- this protein comprises the conserved domain of SEQ ID NO: 35.
- the invention encompasses a plant or plant part comprising at least one copy of a mutant allele of a gene name WOP1 , wherein said gene is the gene encoding a protein of SEQ ID NO: 32, or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form.
- the invention encompasses a plant or plant part comprising at least one copy of a mutant allele of a gene name WOP1 encoding a protein of SEQ ID NO: 32, or a protein comprising at least 95%, 96%, 97%) or 98%) sequence identity to SEQ ID NO: 32 and whereby said protein comprises the conserved domain of SEQ ID NO: 35, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form.
- a mutant allele of a WOP1 protein-encoding gene causes a plant to produce seedless fruits in the absence of pollination and seeded fruits in the presence of pollination, when the plant is homozygous for the mutant allele.
- the mutation in the mutant allele of a WOP1 protein-encoding gene can be any mutation, including deletions, truncations, insertions, point mutations, nonsense mutations, missense or non-synonymous mutations, splice-site mutations, frame shift mutations and/or mutations in regulatory sequences.
- the mutation in the mutant allele of a WOP1 protein-encoding gene is a point mutation.
- the mutation can occur in a DNA sequence comprising the coding sequence of a WOP1 protein-encoding gene or in a RNA sequence encoding a WOP1 protein or it can occur in the amino acid of a WOP1 protein.
- the mutation can occur in the coding sequence or it can occur in non- coding sequences like 5'- and 3 '-untranslated regions, promoters, enhancers etc. of a WOP1 protein - encoding gene.
- RNA encoding a WOP1 protein the mutation can occur in the pre-mRNA or the mRNA.
- the mutant allele results in the protein having a loss-of-function or decrease of function due to one or more amino acids being replaced, inserted and/or deleted, for example resulting in one or more amino acids being replaced, inserted or deleted in the conserved myb-like DNA binding SHAQKYF-class domain or in the SHAQKYF domain.
- truncation of the protein to cause deletion of either or both of these domains, or a part of either of these domains will result in a loss of function or decrease of function of the protein.
- stop codon mutations e.g. in the N-terminal part (amino acid 1 to 96 of SEQ ID NO: 32 or a sequence comprising at least 95% sequence identity to SEQ ID NO: 32) or in one of the conserved domains result in truncated proteins having a reduced function or loss of function.
- amino acid insertions, deletions or replacements in the N-terminal part or one of the conserved domains can result in a protein having a reduced function or loss of function.
- amino acid replacements in the N-terminal part of the protein are E4 (amino acid 4 of SEQ ID NO: 32, Glutamic acid, e.g. to Leucine), S6 (amino acid 6 of SEQ ID NO: 32, Serine, e.g. to Leucine), El 4 (amino acid 14 of SEQ ID NO: 32, Glutamic acid, e.g. to Leucine), P32 ((amino acid 32 of SEQ ID NO: 32, Proline, e.g. to Leucine), A35 (amino acid 35 of SEQ ID NO: 32, Alanine, e.g. to Valine), S54 (amino acid 54 of SEQ ID NO: 32, Serine, e.g.
- amino acid replacements in the conserved domain are PI 04 (amino acid 104 of SEQ ID NO: 32, Proline, e.g. to Leucine) and S143 (amino acid 143 of SEQ ID NO: 32, Serine, e.g. to. Asparagine).
- a further embodiment of the invention therefore concerns plant cells or plants according to the invention comprising a mutant allele of a WOPl protein-encoding gene characterized in that the mutant allele comprises or effects one or more of the mutations selected from the group consisting of a) a deletion, truncation, insertion, point mutation, nonsense mutation, missense or non-synonymous mutation, splice-site mutation, frame shift mutation in the genomic sequence; b) a mutation in one or more regulatory sequences; c) a deletion, truncation, insertion, point mutation, nonsense mutation, missense or non-synonymous mutation, splice-site mutation, frame shift mutation in the coding sequence; d) a deletion, truncation, insertion, point mutation, nonsense mutation, missense or non-synonymous mutation, splice-site mutation, frame shift mutation in the pre-mRNA or mRNA; and/or e) a deletion, truncation, insertion or replacement of
- Reduced expression or no expression means that there is a mutation in a regulatory region of the WOPl gene, such as the promoter, whereby reduced mRNA transcript or no mRNA transcript of the WOPl allele is being made, compared to plants and plant parts comprising a wild type WOPl allele.
- the decrease in the expression can, for example, be determined by measuring the quantity of mRNA transcripts encoding WOPl protein, e.g. using Northern blot analysis or RT-PCR.
- a reduction preferably means a reduction in the amount of RNA transcripts by at least 50%, in particular by at least 70%, optionally by at least 85% or by at least 95%, or even by 100% (no expression) compared to the plant or plant part comprising a wild type WOPl gene.
- Expression can be analysed e.g. in young leaf tissue or ovary tissue, see e.g. Examples.
- the protein comprising one or more amino acids replaced, inserted or deleted compared to the wild type protein.
- one or more amino acids are inserted, deleted or replaced compared to the wild type WOPl protein of SEQ ID NO: 32 or a wild type WOPl protein comprising at least 95%)%), 96%, 97% or 98% sequence identity to SEQ ID NO: 32;
- one or more amino acids are inserted, deleted or replaced compared to the wild type WOPl protein of SEQ ID NO: 33 or a wild type WOPl protein comprising at least 95%%, 96%, 97% or 98% sequence identity to SEQ ID NO: 33;
- one or more amino acids are inserted, deleted or replaced compared to the wild type WOP1 protein of SEQ ID NO: 34 or a wild type WOP1 protein comprising at least 95%%, 96%, 97% or 98%o sequence identity to SEQ ID NO: 34; whereby the mutant protein has reduced function or loss of function compared to the wild type protein and thus
- the WOP1 protein comprises the conserved myb-like DNA binding domain SHAQKYF- class of SEQ ID NO: 35.
- the mutant allele is a mutant allele of the gene WOP1, which gene encodes a protein of SEQ ID NO: 32 (watermelon) or of SEQ ID NO: 33 (cucumber) or of SEQ ID NO: 34 (melon), or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32, SEQ ID NO: 33 or SEQ ID NO: 34, and whereby the protein comprises the conserved domain of SEQ ID NO: 35.
- the myb-like DNA binding domain SHAQKYF-class of SEQ ID NO: 35 is found in the watermelon WOP1 protein of SEQ ID NO: 32 at amino acid 97 to 150, and comprises the SHAQKYF domain at amino acid 143 to 150.
- the wild type WOP1 gene encodes a wild type protein comprising a myb-like DNA binding domain SHAQKYF-class which is 100%) identical to amino acids 97 to 150 of SEQ ID NO: 32.
- the myb-like DNA binding domain SHAQKYF-class of SEQ ID NO: 35 is found in the cucumber WOP1 protein of SEQ ID NO: 33 at amino acid 97 to 150, and comprises the SHAQKYF domain at amino acid 143 to 150.
- the wild type WOP1 gene encodes a wild type protein comprising a myb-like DNA binding domain SHAQKYF-class which is 100%) identical to amino acids 97 to 150 of SEQ ID NO: 33.
- the myb-like DNA binding domain SHAQKYF- class of SEQ ID NO: 35 is found in the melon WOP1 protein of SEQ ID NO: 34 at amino acid 97 to 150, and comprises the SHAQKYF domain at amino acid 143 to 150.
- the wild type WOP1 gene encodes a wild type protein comprising a myb-like DNA binding domain SHAQKYF-class which is 100% identical to amino acids 97 to 150 of SEQ ID NO: 34.
- the mutant allele comprises a mutation whereby one or more amino acids in said myb-like DNA binding domain SHAQKYF-class of SEQ ID NO: 35 (i.e. of amino acids 97 to 150 of SEQ ID NO: 32, SEQ ID NO: 33 and SEQ ID NO: 34) are replaced, inserted or deleted.
- one or more amino acids of the SHAQKYF domain i.e. amino acids 47 to 54 of SEQ ID NO: 35 (i.e. of amino acids 143 to 150 of SEQ ID NO: 32, SEQ ID NO: 33 and SEQ ID NO: 34), are replaced, inserted or deleted.
- amino acids from one amino acid to another amino acid are mentioned herein this includes the start/first and end/last amino acid mentioned.
- at least one amino acid of amino acids of SEQ ID NO: 35 is replaced by another amino acid, preferably amino acid 47 is not a Serine and/or amino acid 8 is not a Proline.
- the Serine at amino acid 47 is replaced by an Asparagine and/or the Proline of amino acid 8 is replaced by a Leucine.
- at least one amino acid of amino acids 47 to 54 of SEQ ID NO: 35 is replaced by another amino acid, preferably amino acid 47 is not a Serine.
- the Serine is replaced by an Asparagine.
- the invention encompasses a plant or plant part comprising at least one copy of a mutant allele of a gene name WOP1 encoding a protein of SEQ ID NO: 32 (in watermelon), SEQ ID NO: 33 (in cucumber) or SEQ ID NO: 34 (in melon), or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32, SEQ ID NO: 33 or SEQ ID NO: 34, respectively, said mutant allele conferring facultative parthenocarpy when the mutant allele is in homozygous form, whereby the protein comprises at least one amino acid substitution in the myb-like DNA binding domain SHAQKYF-class of SEQ ID NO: 35, for example the Serine at amino acid 143 of SEQ ID NO: 32, or at amino acid 143 of SEQ ID NO: 33 or of SEQ ID NO: 34, is replaced by a different amino acid, e.g. an Asparagine, and/or the Proline at amino acid 104 is
- the plants and plant parts comprising at least one copy of a mutant wopl allele may be plants of the family Cucurbitaceae, especially cultivated species such as cucumber ⁇ Cucumis sativus), melon ⁇ Cucumis melo) and watermelon ⁇ Citrullus lanatus). Also plants and plant parts of the family Cucurbitaceae, especially cucumber, melon and watermelon, comprising two copies of a mutant wopl allele are encompassed herein, whereby diploid plants comprising two copies of the mutant wopl allele results in plants exhibiting the phenotype of facultative parthenocarpy.
- the mutant wopl allele is heterozygous in a diploid plant cell or plant, e.g. in a diploid watermelon, cucumber or melon plant. In another aspect the mutant wopl allele is homozygous in a diploid plant cell or plant.
- the plant cells and plants are preferably cultivated plants, such as elite breeding lines or varieties, and not wild plants.
- Cucumber may be any type of cucumber, such as long cucumber, pickling cucumber, slicing cucumber, etc.
- melon may be any type of melon (Galia, Piel de Sapo, Cantaloupe, honeydew, etc.) and watermelon may be any type of watermelon.
- Watermelon plants, and parts thereof, which comprises at least one copy of the mutant wopl allele may be diploid, tetraploid or triploid. In another aspect it may be another polyploid, e.g. a pentaploid, hexaploid, heptaploid, octaploid, etc.
- a tetraploid plant comprising four copies of wopl can for example be used to make an octaploid, by doubling the chromosomes. Crossing such an octoploid with a diploid homozygous for wopl will result in a pentaploid comprising five copies of wopl.
- the polyploidy watermelon plant comprises at least one copy of the mutant wopl allele, but it may also comprise more copies, e.g. in a preferred aspect it is homozygous for wopl and lacks the wild type WOP1 allele.
- all chromosomes 4 comprise the mutant wopl allele.
- a diploid plant may thus have the genotype wopl/WOPl (heterozygous for the mutant allele) or wopl/wopl (homozygous for the mutant allele).
- the diploid plant comprising the wopl allele in homozygous form is a double haploid plant (DH), e.g. a double haploid watermelon, cucumber or melon plant or plant cell or plant part.
- DH double haploid plant
- a triploid watermelon plant may have the genotype wop 1 /WOP 1 /WOP 1 or wopl /wopl/WOPl or wopl/wopl/wopl.
- the triploid plant with genotype wop 1 /WOP 1 /WOP 1 can be made by crossing a wild type female tetraploid (WOPl/ WOP 1 /WOP 1 /WOP 1) with a diploid male homozygous for the mutant allele ⁇ wopl/wopl).
- the triploid plant with genotype wopl /wopl /WOPl can be made by crossing a female tetraploid (wopl/ wopl/wopl/wopl) with a diploid male homozygous for the wild type allele (WOPl /WOPl).
- a tetraploid watermelon plant may have the genotype wopl/ WOPl /WOPl /WOPl or wopl /wopl /WOPl /WOPl or wopl /wopl /wopl /WOPl or wop 1 /wopl /wopl /wop 1.
- the genotypes wopl /wopl /WOPl /WOPl can be made by doubling the chromosomes of a diploid wopl/WOPl .
- the genotypes wopl /wopl /wopl /wopl can be made by doubling the chromosomes of a diploid wopl/wopl .
- wopl/ WOPl /WOPl /WOPl and wopl /wopl /wopl /WOPl can for example be made by crossing two tetraploids of genotype wopl /wopl /WOPl /WOPl and identifying the genotypes in the progeny.
- the watermelon plant is homozygous for wopl, in another aspect it is heterozygous for wopl. In one aspect it is an inbred line or a variety. In a further aspect it is an Fl hybrid.
- Seeds from which any of the watermelon plants, cucumber plants or melon plants described can be grown are also encompassed herein, as are parts of such a plant, such as seedless fruits produced in the absence of pollination, flowers, cells, roots, rootstocks, scions, leaves, stems, vegetative propagations, cuttings, seed propagations (e.g. sellings) and also in vitro cell- or tissue cultures, as well as pollen, ovaries, etc. are encompassed herein.
- the watermelon plant or cucumber or melon plant is a diploid line (e.g. an inbred line) or variety, comprising at least one mutant copy of wopl, preferably two mutant copies (i.e. is homozygous for wopl).
- the diploid plant homozygous for wopl will produce fruits which are seedless. When pollination does occur, the fruits will be seeded.
- a diploid plant which is homozygous for wopl, and which additionally is male sterile.
- Male sterility is the failure of plants to produce functional anthers, pollen, or male gametes.
- Several male sterility genes have been identified in watermelon, including the ms-1 gene.
- the ms-1 nuclear gene controls male sterility and, in plants with an ms-1 gene in homozygous form ⁇ ms-1 is recessive), the normal development of anthers is hindered while female flower development is normal. The gene eliminates pollen production.
- the diploid plant and plant part according to the invention is male sterile and/or comprises a male sterility gene.
- the male sterility gene is a recessive gene
- the plant and plant part preferably comprises the gene in homozygous form.
- the watermelon plant comprises the ms-1 gene, preferably in homozygous form.
- the diploid watermelon plant comprises on chromosome 4 the mutant wopl gene in homozygous form ⁇ wopl/wopl) and further comprises a male sterility gene, e.g. ms-1, in homozygous form, e.g. if the male sterility gene is recessive (e.g. ms- 1/ms-l) or optionally in heterozygous form if the male sterility is dominant.
- One preferred plant is a diploid plant homozygous for wopl and homozygous for ms-1.
- a further way of ensuring that plants according to the invention, especially diploid watermelon plants, produce seedless fruits at all times (not only in the absence of pollination) is to combine the wopl gene in homozygous form with a gene conferring stenospermocarpy, so that if pollination does occur the fruits will be seedless despite pollination.
- the stenospermocarpy gene is the recessive gene called embl.
- the wild type and mutant Embl gene has been described in co-pending application EP16171462.1.
- the Embl gene encodes a cyclin SDS like protein. When the mutant allele embl is in homozygous form, stenospermocarpy results.
- Stepnospermocarpy means that induction of fruit set and development requires pollination but without the fruits producing mature or viable seeds. Mature or viable seeds are not developed in stenospermocarpic plants due to arrested seed development or degradation of ovules and/or embryos and/or endosperm or abortion of the ovules and/or embryos and/or endosperm before maturity is reached. Thus, when diploid plants homozygous for a mutant embl allele ⁇ embl/embl) are self-pollinated or pollinated by pollen from another plant, they produced seedless, diploid fruits.
- the diploid watermelon plant comprises on chromosome 4 the wopl gene in homozygous form ⁇ wopl /wopl) and further comprises a stenospermocarpy gene, e.g. embl, in homozygous form, e.g. if the stenospermocarpy gene is recessive (e.g. embl/embl) or optionally in heterozygous form if the stenospermocarpy gene is dominant.
- a stenospermocarpy gene e.g. embl
- a stenospermocarpy gene in homozygous form, e.g. if the stenospermocarpy gene is recessive (e.g. embl/embl) or optionally in heterozygous form if the stenospermocarpy gene is dominant.
- a stenospermocarpy gene e.g. embl
- embl in homo
- One mutant allele of embl can be obtained from the watermelon seeds being heterozygous or homozygous for the mutant allele of the cyclin SDS like protein encoding gene (also referred to as Embl gene), deposited by Nunhems B.V. under NCIMB 42532. Of these seeds 25% contain the mutant allele (see mRNA of SEQ ID NO: 27) encoding a mutant protein of SEQ ID NO: 28.
- the wild type allele of the Embl gene can be obtained from the watermelon seeds being heterozygous or homozygous for the wild type cyclin SDS like protein encoding gene, deposited by Nunhems B.V. under NCIMB 42532.
- seed 25% contain the wild type allele of SEQ ID NO: 25 in homozygous form, encoding the wild type protein of SEQ ID NO: 26.
- Other mutant alleles of the Embl gene can be generated de novo, e.g. by mutagenesis or by other methods known to the skilled person.
- the genomic Embl nucleotide sequence shown under SEQ ID NO: 25 encodes a wild type cyclin SDS like protein of Citrullus lanatus having the amino acid sequence as shown under SEQ ID NO: 26.
- the mRNA sequence shown under SEQ ID NO: 27, and the mutant protein shown under SEQ ID NO: 28, is of the mutant embl allele found in seeds deposited under NCIMB42532.
- a mutant allele of embl causes a plant to be male fertile but producing seedless fruits, when the plant is homozygous for the mutant allele.
- the mutation in the Embl gene can be any mutation, including deletions, truncations, insertions, point mutations, nonsense mutations, missense or non-synonymous mutations, splice-site mutations, frame shift mutations and/or mutations in regulatory sequences.
- the mutation is a point mutation and/or splice-site mutation.
- the mutation can occur in a DNA sequence comprising the coding sequence of a cyclin SDS like protein encoding gene (Embl gene) or in a RNA sequence encoding a cyclin SDS like protein or it can occur in the amino acid of a cyclin SDS like protein (or Embl protein).
- a DNA sequence of a cyclin SDS like protein encoding gene the mutation can occur in the coding sequence (cds, composed of the exons) or it can occur in non-coding sequences like 5'- and 3 '-untranslated regions, introns, promoters, enhancers etc. of a cyclin SDS like protein encoding gene.
- RNA encoding a cyclin SDS like protein the mutation can occur in the pre-mRNA or the mRNA.
- Diploid Citrullus lanatus seeds of plants segregating for a mutant allele of a cyclin SDS like protein encoding gene have been deposited by Nunhems B.V. under the Budapest Treaty under accession No. NCIMB 42532 at NCIMB Ltd., Ferguson Building, Craibstone Estate Bucksburn Aberdeen AB21 9YA, Scotland, UK on 27 January 2016.
- the allele of the cyclin SDS like protein encoding gene was designated embl.
- the deposited seeds were obtained from a self-pollinated back-cross of a plant homozygous for the embl mutant allele with plants homozygous for the embl wild type allele.
- the invention therefore, relates to a diploid watermelon plant or plant part comprising at least one copy of the mutant wopl allele, preferably two copies, and at least one copy of a mutant embl allele, preferably two copies of a mutant embl allele.
- the mutant embl allele is the allele found in seeds deposited under NCIMB 42532.
- the mutant wopl allele is the allele found in seeds deposited under NCIMB42533 or a different mutant wopl allele as described.
- diploid plant, or seeds from which the plant can be grown, or tissue or parts of the plant comprises a mutant wopl allele as described above, e.g. the mutant allele as found in seeds deposited under NCIMB42533 or a different mutant wopl allele.
- Tetraploid watermelon plants comprising a mutant wopl allele
- Seedless triploid watermelon production involves using pollen from diploid male parent plants to fertilize flowers of tetraploid maternal parent plants. Pollination of the tetraploid flowers with diploid pollen leads to Fl seeds which are triploid (Kihara, 1951, Proceedings of American Society for Horticultural Science 58: 217-230; Eigsti 1971, Hort Science 6: 1-2).
- the triploid hybrid plants, grown from these Fl seeds are self- infertile as they produce sterile pollen due to chromosome imbalance. The triploid hybrids, therefore, normally need to be pollinated by a diploid pollenizer to produce watermelon fruit.
- a triploid plant comprising three copies of a mutant wopl gene produce fruits without pollination and there is no need anymore for a pollenizer plant being present.
- both tetraploid plants comprising four copies of a recessive wopl allele, for use as a female parent, and diploid plants comprising two copies of a recessive wopl allele, for use as a male parent, are provided, as well as triploid Fl hybrids (comprising three copies of a mutant wopl allele) produced by crossing the diploid male parent with the tetraploid female parent.
- triploid Fl hybrids comprising three copies of a mutant wopl allele
- Chromosome doubling techniques known to the skilled person may be used to generate a tetraploid plant from such diploid plants.
- an antimitotic agent such as colchicine, dinitoalanine, or oryzalin, in order to induce chromosome doubling.
- tissue culture may be used to generate tetraploid plants from plant parts. To verify that plants are tetraploid chromosome number can be confirmed. Ploidy can be easily determined by chromosome counting or flow cytometry or other known methods (Sari et al. 1999, Scientia Horticulturae 82: 265 - 277, incorporated herein by reference) .
- a tetraploid cultivated watermelon plant of the species Citrullus lanatus comprising four copies of a mutant wopl allele (as described above), one on each of the four chromosomes 4.
- the wopl allele is found in the region as described above, between one or more of the SNP markers as described further above and/or linked to one or more of the sequences SEQ ID NO: 1 (or SEQ ID NO: 29) to SEQ ID NO: 24 as described above.
- the mutant wopl allele applies equally to the tetraploid. So for example the tetraploid plant may comprise four copies of the wopl allele as found in seeds deposited under NCIMB42533, or four copies of a different mutant wopl allele as described further above.
- the invention encompasses a tetraploid watermelon plant or plant part comprising one, two, three or four copies of a mutant allele of a gene name WOP1 encoding a protein of SEQ ID NO: 32, or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32 (said protein optionally comprising the conserved domain of SEQ ID NO: 35).
- the aspects regarding the mutant wopl allele described above for diploid watermelon plants comprising one or two copies of a mutant wopl allele apply to the tetraploid plants and plant parts. So, for example, in one aspect the mutant allele results in reduced expression or no expression of the WOP1 gene or the mutant allele encodes a protein having a decreased function or a loss-of-function.
- the tetraploid watermelon plant or plant part comprises four copies of the allele encoding the mutant WOP1 protein of SEQ ID NO: 31.
- the tetraploid watermelon plant or plant part comprises four copies of a different mutant wopl allele, e.g. selected from the alleles described above.
- Genotyping of tetraploid plants or plant parts can be done in the same way as for diploids, using for example a KASP-assay to distinguish SNP genotypes, e.g. plants or parts comprising AAAA for SNP1 can be distinguished from plants or parts comprising GAAA, GGAA, GGGA or GGGG for SNP1 in their genome. Plants and plant parts comprising AAAA for SNP16a, i.e. four copies of SEQ ID NO: 30 encoding the mutant WOP1 protein of SEQ ID NO: 31, can equally be distinguished from the other genotypes.
- a tetraploid watermelon comprising at least one or two or three copies of the mutant wopl allele (as described above), but preferably comprising four copies of the mutant wopl allele (as described above) is provided.
- the watermelon plant is a tetraploid inbred female line, suitable as a parent for Fl hybrid seed production.
- the generation of the tetraploid female inbred line can be carried out by using a diploid plant, comprising one or preferably two copies of the wopl allele in order to double the chromosomes and generate a tetraploid plant.
- a diploid inbred line homozygous for wopl can be used to generate the tetraploid plant.
- plants grown from seeds deposited under NCIMB42533 comprising two copies of a mutant wopl allele can be used.
- a tetraploid plant comprising four copies of a mutant wopl allele will express the phenotype, i.e. be facultative parthenocarpic.
- Seeds from which such a tetraploid plant can be grown are also encompassed herein, as are parts of such a plant, such as tetraploid seedless fruits produced in the absence of pollination, flowers, leaves, stems, cuttings, vegetative propagations, cells, seed propagations (e.g. sellings) and also in vitro cell- or tissue cultures, as well as pollen, ovaries, rootstocks, scions, etc. are encompassed herein.
- the tetraploid plant, or seeds from which the plant can be grown, or tissue or parts of the plant (pollen, anthers, ovules) comprises a mutant wopl allele as described above, e.g. the mutant allele as found in seeds deposited under NCIMB42533 or another mutant wopl allele.
- a tetraploid can comprise different mutant wopl alleles, e.g. two mutant wopl alleles encoding a truncated WOP1 protein and two mutant wopl allele encoding a WOP1 protein having an amino acid substitution, e.g. Serine 143 of SEQ ID NO: 32 being replaced by Asparagine (mutant S143N).
- Such plants can for example be made by first making a diploid comprising different mutant wopl alleles and then doubling the chromosomes of such diploid.
- the tetraploid does, however, comprise four copies of the same mutant wopl allele, i.e. the tetraploid is made from a diploid which is homozygous for the wopl allele.
- Triploid watermelon plants comprising a mutant wopl allele
- triploid watermelon seeds, plants and plant parts comprising one, two or three copies of a mutant wopl allele are provided, i.e. wop 1 /WOP 1 /WOP 1 or wop 1 /wopl /WOP 1 or wopl /wopl /wopl, respectively.
- Such triploids can be made as described above, and as shown in the Table 2 below: Table 2
- a tetraploid plant comprising four copies of a mutant wopl allele is used as female parent and is pollinated with pollen of diploid male parent comprising two copies of a mutant wopl allele and the seeds from the cross are harvested.
- These seeds are triploid and they comprise three copies of a mutant wopl allele of the invention (Table 2, row A). Plants grown from these seeds produce seedless watermelon fruits (triploid fruits) without the need for pollination to induce fruit set.
- the triploid hybrid plants, grown from these Fl triploid seeds are self-infertile as they produce sterile pollen due to chromosome imbalance. These seeds can thus be grown in production fields without the need for pollenizer plants. This is the first time that seedless triploid watermelon fruits can be produced in the absence of pollen and pollenizer plants.
- the triploid under A above comprises three identical mutant wopl alleles, i.e. the female and male parents comprise the same mutant allele.
- the female parent and the male parent may comprise different mutant wopl alleles.
- the female parent may comprise four mutant wopl allele encoding a truncated WOP1 protein and the male parent may comprise two mutant wopl allele encoding a WOP1 protein having an amino acid substitution, e.g. Serine 143 of SEQ ID NO: 32 being replaced by Asparagine (mutant S143N), or the other way around.
- the triploid, seedless fruits are preferably marketable. Preferably they have an average brix of at least 6.0, 7.0, 8.0 or preferably at least 9.0, preferably at least 10.0, more preferably at least 11.0.
- Fruits may be of any size, shape, color and rind pattern. Preferably fruit flesh color at maturity is uniform. In one aspect fruit flesh is red or dark red.
- the average fruit weight of a triploid hybrid comprising wopl in three copies may be equal to or above 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13 or 14 kg. In another embodiment average fruit weight of a triploid hybrid comprising wopl in three copies may be equal to or less than 5 kg, e.g. 4, 3, 2, 1.5 or 1 kg or even less.
- Seedless fruits may be of any shape (e.g. elongate, oval, blocky, spherical or round), fruit surface (furrow, smooth), flesh color (red, dark red, scarlet red, coral red, orange, salmon, pink, pinkish red, yellow, canary yellow or white), rind color (e.g.
- the mutant wopl allele may be used to breed a range of seedless varieties, producing fruits of different shapes and sizes, etc. by traditional breeding. See Guner and Wehner 2004, Hort Science 39(6): 1175-1182, in particular pages 1180-1181 describing genes for fruit characteristics. Generally important breeding objectives are early maturity, high fruit yield, high internal fruit quality (good uniform color, high sugar, proper sugar : acid ratio, good flavor, high vitamin and lycopene content, firm flesh texture, non-fibrous flesh texture, freedom from defects such as hollow heart, rind necrosis, blossom-end rot or cross stitch and good rind characteristics and cracking-resistance).
- Triploid Fl hybrid plants Seeds from which such triploid Fl hybrid plants can be grown are one aspect of the invention.
- triploid seeds and triploid plants comprising only one or two copies of a mutant wopl allele of the invention (as shown in the Table 2 above, row B and C)
- the phenotype has not yet been tested, but these may also be suitable to produce seedless fruits without pollen and they may also be grown in a field without pollenizer plants.
- such triploid plants and seeds from which such plants can be grown are an aspect of the invention, as are parts thereof and triploid fruits produced by such plants.
- triploid fruits are marketable.
- Fruits may be of any size, shape, color and rind pattern.
- fruit flesh color at maturity is uniform. In one aspect fruit flesh is red or dark red.
- the triploid plant of the invention is a vegetative propagation. Also provided is a method for producing triploid hybrid watermelon seeds, wherein triploid plants grown from such seeds produce fruits in the absence of pollination, said method comprising:
- Also provided is a method for producing triploid hybrid watermelon seeds comprising: (a) providing a diploid watermelon plant lacking a mutant wopl allele and a tetraploid plant comprising four copies of a mutant wopl allele (see e.g. Table 2 row B), or providing a diploid watermelon plant homozygous for the mutant wopl allele and a tetraploid plant lacking a mutant wopl allele (e.g. Table 2 row C),
- the dried and harvested Fl seeds are then packaged. They may also be treated prior to packaging.
- packages or containers comprising or consisting of seeds obtained by the above method are an embodiment herein.
- Triploid plants from which any the above triploid plants can be grown are also encompassed herein, as are parts of such a plant, such as triploid fruits, flowers, leaves, stems, cuttings, vegetative propagations, cells, seed propagations (e.g. sellings) and also in vitro cell- or tissue cultures, as well as pollen, ovaries, rootstocks, scions, etc. are encompassed herein.
- the triploid plant, or seeds from which the plant can be grown, or tissue or parts of the plant comprises a mutant wopl allele as described above, e.g. the mutant allele as found in seeds deposited under NCIMB42533 or another mutant wopl allele as described above.
- diploid plants, tetraploid plants or triploid plants (or other polyploids) can also be reproduced vegetative ly (clonally) and such vegetative ly propagated plants, or 'vegetative propagations' are an embodiment of the invention. They can easily be distinguished from other watermelon plants by the presence of a mutant wopl allele and/or phenotypically. The presence of one or more mutant wopl alleles can be determined as described elsewhere herein.
- Vegetative propagations can be made by different methods.
- one or more scions of a plant of the invention may be grafted onto a different rootstock, e.g. a biotic or abiotic stress tolerant rootstock.
- Other methods include in vitro cell or tissue culture methods and regeneration of vegetative propagations from such cultures.
- Such cell or tissue cultures comprise or consist of various cells or tissues of a plant of the invention.
- such a cell or tissue culture comprises or consists of vegetative cells or vegetative tissues of a plant of the invention.
- a cell or tissue culture comprises or consists of reproductive cells or tissues, such as anthers or ovules of a plant of the invention.
- Such cultures can be treated with chromosome doubling agents to make e.g. double haploid plants, or they can alternatively be used to make haploid plants (e.g. to make diploids from a tetraploid or to make haploids from a diploid).
- An in vitro cell or tissue culture may, thus, comprise or consist of cells or protoplasts or plant tissue from a plant part selected from the group consisting of: fruit, embryo, meristem, cotyledon, pollen, ovule, leaf, anther, root, root tip, pistil, flower, seed, stem. Also parts of any of these are included, such as e.g. only the seed coat (maternal tissue).
- a cell culture or a tissue culture of cells of a plant comprising one, two, three or four copies of a mutant wopl allele, all as described above is provided.
- a cell culture or a tissue culture comprises cells or protoplasts or plant tissue from a plant part of a plant comprising a mutant wopl allele may comprise or consist of cells or tissues selected from the group consisting of: embryo, meristem, cotyledon, pollen, leaf, anther, root, root tip, pistil, flower, seed, stem; or parts of any of these.
- a watermelon plant regenerated from such a cell culture or tissue culture wherein the regenerated plant (or progeny thereof, e.g. obtained after selling the regenerated plant) comprises the mutant wopl allele. Therefore, in one aspect the watermelon plant comprising a mutant wopl allele in one or more copies is a vegetatively propagated watermelon plant.
- the cells and tissues of the invention are non-propagating cells or tissues.
- a method for seedless triploid watermelon fruit production comprising:
- step 3 harvesting the seedless watermelon fruits produced on the triploid plants, whereby the fruits are preferably produced without pollination of the female flowers.
- the triploid hybrid plant of step 1 is preferably not grafted onto a different rootstock.
- the method can also be described as a method of producing seedless watermelon fruits, said method comprising growing a triploid plant comprising at least one, preferably two, more preferably three copies of mutant wopl allele and harvesting the fruits produced by said plants.
- the fruits develop preferably without pollination of the female flowers, i.e. in the absence of viable pollen. No insects, such as bees, are required anymore for fruit set, i.e. placing bee hives into or near the fields is not necessary.
- the harvested triploid fruits may be packaged for fresh markets or for processing.
- Fruits comprising one, two or three wopl alleles obtainable by the above method are encompassed herein.
- detection of the mutant wopl allele e.g. by detection of the mutant wopl allele using DNA, RNA or protein detection as described elsewhere, e.g. by PCR, genotyping or marker analysis of markers linked to (or closely linked to) the wopl allele, can distinguish such fruits.
- harvested triploid fruits i.e.
- wop 1 /WOP 1 /WOP 1 or wop 1 /wopl /WOP 1 or wopl /wopl /wopl) are provided, such as packaged whole fruits or fruit parts and/or processed fruits or fruit parts.
- Also provided is a method for production of a facultative parthenocarpic cultivated watermelon plant comprising the steps of a) introducing mutations in a population of watermelon plants or providing a mutant population of watermelon plants;
- a watermelon plant produced by the above method is encompassed.
- the population of watermelon plants under a) is preferably a single genotype of a cultivated watermelon breeding line or variety, which is treated / has been treated with (or subjected to) a mutagenic agent, or progeny of such a population e.g. obtained after selling individuals of the population to produce M2, M3 or further generation plants. This may for example be a TILLING population.
- plants are screened for the phenotype, i.e. for being facultative parthenocarpic and/or the plants (or plant parts or DNA therefrom) are screened for the presence of a mutant allele of the WOPl gene, i.e.
- phenotypic screening can be done in several steps. For example first plants can be grown in an insect free environment and male flowers can be removed. Female flowers can be observed visually for flowering and fruit development (in absence of pollen). The developed fruit can be cut in half at maturity to check if these are seedless. Selected plants can e.g. be vegetatively reproduced to confirm the parthenocarpy phenotype and/or to e.g.
- Step c) can involve various methods to determine whether a mutant wopl allele is present. For example an allelism test with plants deposited herein can be carried out. Alternatively or in addition marker analysis or sequence analysis of the chromosome 4 region comprising the WOPl locus can be carried out, or PCR or RT-PCR can be used to amplify the wopl allele (or a part thereof) or the mRNA (cDNA). Also genetic analysis to determine the recessive inheritance may be carried out.
- a facultative parthenocarpic watermelon plant for producing seedless watermelon fruits is provided, preferably without pollination of the female flowers of the plant.
- a mutant wopl allele for generating facultative parthenocarpic watermelon plants and/or seedless watermelon fruits in the absence of pollination of the female flowers is provided.
- a mutant wopl allele of a WOPl gene according to the invention for producing facultative parthenocarpic watermelon plants is encompassed herein.
- the plants, plant parts and plant cells according to the invention are not exclusively obtained by means of an essentially biological process as defined by Rule 28 (2) EPC (European Patent Convention).
- the plants are non-GMO (not genetically modified).
- the mutant allele of the WOPl gene comprises a human induced mutation, i.e. a mutation introduced by mutagenesis techniques, such as chemical mutagenesis or UV mutagenesis, or targeted mutagenesis techniques.
- an isolated mutant WOPl protein and an isolated wild type WOPl protein is provided or an isolated nucleic acid molecule encoding a mutant WOPl protein or a wild type WOPl protein. Also an antibody able to bind a mutant or wild type WOPl protein is encompassed herein.
- a screening method for identifying and/or selecting seeds, plants or plant parts or DNA from such seeds, plants or plant parts comprising in their genome a mutant allele of a WOPl protein- encoding gene is provided.
- the method comprises screening at the DNA, RNA (or cDNA) or protein level using known methods, in order to detect the presence of the mutant allele. There are many methods to detect the presence of a mutant allele of a gene.
- a method for screening and/or selecting plants or plant material or plant parts, or DNA or RNA or protein derived therefrom, for the presence of a mutant wopl allele comprising one or more of the following steps: a) determining if the gene expression of the endogenous WOPl gene is reduced or abolished; b) determining if the amount of wild type WOPl protein is reduced or abolished;
- Routine methods can be used, such as RT-PCR, PCR, antibody based assays, sequencing, genotyping assays, phenotyping for steps e and f, etc.
- the plants or plant material or plant parts may be watermelon, cucumber or melon plants or plant materials or plant parts, such as leaves, leaf parts, cells, fruits, fruit parts, ovaries, stem, hypocotyl, seed, parts of seeds, seed coat, embryo, etc.
- a SNP genotyping assay can be used to detect whether a plant or plant part or cell comprises the wild type nucleotide or the mutant nucleotide in its genome.
- the SNP can easily be detected using a KASP-assay (see world wide web at kpbioscience.co.uk) or other SNP genotyping assays.
- KASP-assay see world wide web at kpbioscience.co.uk
- For developing a KASP-assay for example 70 base pairs upstream and 70 base pairs downstream of the SNP can be selected and two allele-specific forward primers and one allele specific reverse primer can be designed. See e.g. Allen et al. 2011, Plant Biotechnology J. 9, 1086-1099, especially p097-1098 for KASP-assay method.
- genotyping assays can be used.
- a TaqMan SNP genotyping assay a High Resolution Melting (HRM) assay
- HRM High Resolution Melting
- SNP- genotyping arrays e.g. Fluidigm, Illumina, etc.
- DNA sequencing may equally be used.
- a method for determining, or detecting or assaying, whether a cell or of a watermelon plant or plant part comprises a mutant allele of a gene name WOP1 encoding a protein of SEQ ID NO: 32, or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 32 is provided herein.
- the method comprises determining the expression of the allele, and/or determining the coding sequence of the allele and/or determining part of the coding sequence of the allele (e.g. a SNP genotype of the allele), and/or determining the amino acid sequence of the protein produced and/or the amount of protein produced.
- a method for determining, or detecting or assaying, whether a cell or of a cucumber or melon plant or plant part comprises a mutant allele of a gene name WOP1 encoding a protein of SEQ ID NO: 33, or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 33 (cucumber), or a protein of SEQ ID NO: 34, or a protein comprising at least 95%, 96%, 97% or 98% sequence identity to SEQ ID NO: 34 (melon).
- a plant or part thereof comprises a mutant wopl allele of the invention.
- the mRNA (or cDNA) level of the wild type allele may be determined, or the wild type protein level may be determined, to see if there is a reduced expression or no expression of the wild type allele.
- the coding sequence or part thereof may be analysed, for example if one already knows which mutant allele may be presence, an assay can be developed to detect the mutation, e.g. a SNP genotyping assay can e.g. distinguish between the presence of the mutant allele in watermelon and the wild type allele, e.g. genotyping for SNP16a.
- a method for selection of a plant comprising the steps of: a) identifying a plant which has a mutation in an allele encoding a WOP1 protein-encoding gene wherein the wild type allele of the gene encodes a WOP1 protein comprising at least 95%, 96%, 97% or 98%) sequence identity to any one of the proteins selected from the group of: SEQ ID NO:32 or SEQ ID NO: 33 or SEQ ID NO: 34, and optionally b) determining whether the plant, or a progeny plant produced by self-fertilization, is facultative parthenocarpic and optionally c) selecting a plant comprising at least on copy of the mutant allele of step a).
- a method for production of a plant comprising the steps of: a) introducing mutations in a population of plants, b) selecting a plant producing seedless fruit in the absence of pollination and seeded fruits after pollination and/or comprising a mutant wopl allele, c) optionally verifying if the plant selected under b) has a mutation in an allele encoding a WOP1 protein encoding gene and selecting a plant comprising such a mutation, and optionally d) growing/cultivating the plants obtained under c), wherein the wild type allele of the gene encodes a WOP1 protein comprising at least 95% sequence identity to any one of the proteins selected from the group of: SEQ ID NO:32 or SEQ ID NO: 33 or SEQ ID NO: 34.
- a method for production of a plant comprising the steps of: a) introduction of a foreign nucleic acid molecule into a plant, wherein the foreign nucleic acid molecule is chosen from the group consisting of i) DNA molecules, which code at least one antisense RNA, which effects a reduction in the expression of an endogenous gene encoding a WOP1 protein; ii) DNA molecules, which by means of a co-suppression effect lead to the reduction in the expression of an endogenous gene encoding a WOP1 protein; iii) DNA molecules, which code at least one ribozyme, which splits specific transcripts of an endogenous gene encoding a WOP1 protein; iv) DNA molecules, which simultaneously code at least one antisense RNA and at least one sense RNA, wherein the said antisense RNA and the said sense RNA form a double-stranded RNA molecule, which effects a reduction in the expression of an endogenous gene encoding a WOP1 protein (RNA
- a genetically modified plant and plant part whereby the plant has reduced expression or no expression of the endogenous WOPl gene, e.g. through silencing of the endogenous WOPl gene.
- a plant may be any plant, in one aspect it is a watermelon, melon or cucumber. However, it can also be a maize, soybean, wheat, canola, tomato, cotton, etc.
- a plant and plant part is provided comprising a mutation in the endogenous WOPl gene, e.g. an induced mutation generated e.g. by targeted mutagenesis, whereby either the gene expression is reduced or abolished or the expressed gene encodes a reduced function or loss of function WOPl protein compared to the wild type protein.
- Such a plant may be any plant, in one aspect it is a watermelon, melon or cucumber as described. However, it can also be a maize, soybean, wheat, canola, tomato, cotton, pepper, etc.
- the WOPl gene in other species may have less sequence identity to the Cucurbitaceae WOPl gene, it is encompassed herein that in this aspect of the invention the WOPl gene is a gene encoding a protein comprising at least 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95% sequence identity to SEQ ID NO: 32.
- the WOP1 gene is a gene encoding a protein comprising at least 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95% sequence identity to SEQ ID NO: 32 whereby the protein comprises the conserved domain of SEQ ID NO: 35 or a sequence comprising at least 70%, 75%, 80%, 85%), 90%), 95% sequence identity to SEQ ID NO: 35.
- the skilled person can identify orthologs of the WOP1 gene in such other species, e.g. in pepper or tomato, and thereby make facultative parthenocarpic pepper or tomato plants.
- Diploid Citrullus lanatus seeds of plants segregating for a mutant wopl allele have been deposited by Nunhems B.V. under the Budapest Treaty under accession No. NCIMB42533 at NCIMB Ltd., Ferguson Building, Craibstone Estate, Bucksburn Aberdeen AB21 9YA, Scotland, UK on 27 January 2016.
- the seeds were produced by selling a plant heterozygous for the mutant wopl allele (i.e. WOPl/wopl).
- the deposited seeds consist of 25% WOP1/WOP1 (homozygous wild type WOP1 allele), 50% WOPl/wopl (heterozygous) and 25%> wopl/wopl (homozygous for the mutant wopl allele) plants.
- Diploid Citrullus lanatus seeds of plants segregating for a mutant allele of a cyclin SDS like protein encoding gene have been deposited by Nunhems B.V. under the Budapest Treaty under accession No. NCIMB 42532 at NCIMB Ltd., Ferguson Building Craibstone Estate Bucksburn Aberdeen AB21 9YA, Scotland, UK on 27 January 2016. The deposited seeds were obtained from a self-pollinated back-cross of a plant homozygous for the embl mutant allele with plants homozygous for the embl wild type allele.
- the Applicant requests that samples of the biological material and any material derived from said samples be only released to a designated Expert in accordance with Rule 32(1) EPC or related legislation of countries or treaties having similar rules and regulation, until the mention of the grant of the patent, or for 20 years from the date of filing if the application is refused, abandoned, withdrawn or deemed to be withdrawn.
- SEQ ID NO 1 - 24 and SEQ ID NO 29 Sequences of Citrullus lanatus comprising Single Nucleotide Polymorphisms on chromosome 4, said SNPs being polymorphic between plants comprising the mutant wopl allele and plants lacking the mutant wopl allele of seeds deposited under NCIMB42533.
- SEQ ID NO 25 Genomic sequence of a wild type cyclin SDS like protein encoding gene (Embl gene) from Citrullus lanatus.
- SEQ ID NO 26 Amino acid sequence of a SDS like protein from Citrullus lanatus. The amino acid sequence is derivable from the coding sequence of SEQ ID NO 25.
- SEQ ID NO 27 mRNA sequence of a mutant allele of a cyclin SDS like protein from Citrullus lanatus.
- SEQ ID NO 28 Amino acid sequence of the mutant allele of a SDS like protein. The amino acid sequence is derivable from SEQ ID NO 27.
- SEQ ID NO 30 cDNA and genomic DNA of watermelon encoding the mutant WOPl protein of SEQ
- SEQ ID NO 31 Amino acid sequence of a mutant WOPl protein, comprising an S143N mutation, as found in seed deposited under NCIMB42533.
- SEQ ID NO 32 Amino acid sequence of a wild type WOPl protein of watermelon
- SEQ ID NO 33 Cucumis sativus wild type WOPl protein
- SEQ ID NO 34 Cucumis melo wild type WOPl protein
- SEQ ID NO 35 conserved domain "myb-like DNA binding domain SHAQKYF-class" comprised in the WOPl proteins of SEQ ID NO: 32, SEQ ID NO: 33 and SEQ ID NO: 34
- SEQ ID NO 36 to 38 primer pair for WOPl gene expression analysis and resulting amplified product
- SEQ ID NO 39 to 41 primer pair for WOPl gene expression analysis and resulting amplified product
- a mutant population was established by treating approximately 10.000 watermelon seeds from an inbred diploid line with EMS several hours and subsequently washing the seeds in streaming tap water for 30 minutes. After that the seeds were kept wet until sowing in soil. Ml Plants were grown from the mutagenized seeds, self-pollinated and the seeds (M2 generation) were harvested.
- Propagation of the wopl mutant plant was performed by grafting cuttings of the wopl mutant plant to rootstock of a non-mutagenized watermelon plant. The plant was analysed to confirm that the fruit setting was not coming from accidental insect pollination or from hermaphroditic flowers. The plant phenotype was confirmed in two growing seasons. Pollination of the female flowers led to normal, seeded fruits, while in the absence of pollination seedless fruits developed.
- the wopl gene is a single recessive gene.
- An homozygous wopl mutant was back-crossed with the original non-mutagenized watermelon inbred line, (BC1 generation). 25% of the plants grown from the self-pollinated BC1 generation did produce seedless fruits without pollination. Results show that the wopl mutation is due to a single recessive gene.
- the mutant wopl allele was mapped to chromosome 4, between SNPla and SNP24, especially between SNPl and SNP24, most likely between SNP3 and SNP23.
- the protein contained a conserved myb-like DNA binding domain SHAQKYF-class (highlighted in boxes above) and the amino acid substation was in the SHAQKYF motif of the domain. This motif is a conserved motif having amino acids SH[A/L]QKY[R/F]L and is part of an alpha-helix.
- the modified leaf morphology can therefore be used as a phenotypic trait in distinguishing plants homozygous or heterozygous for the mutant wopl allele from plants lacking the mutant wopl allele and only comprising the wild type allele (WOP 1 /WOP 1).
- Two backcross inbred lines heterozygous for the mutant wopl allele could not be clearly distinguished from the wild type plant, indicating that the genetic background may influence the expression of the morphology when the allele is in heterozygous form.
- proteins also contain the myb-like DNA binding domain SHAQKYF-class (highlighted in boxes above).
- the proteins each have 95.3% sequence identity to the wild type watermelon WOPl protein (SEQ ID NO: 32) and comprise 98.7% sequence identity to each other using the program Needle of website ebi.ac.uk with default parameters).
- RT-PCR analysis was carried out to determine mRNA expression in the wopl mutant plant and in the WOPl wild type plant. Tissue samples were taken from young leaf tissue, ovary tissue of open flowers, ovary tissue at 3-4 and 5-6 days after pollination/fruit development of both wild type and mutant plants.
- Two primer combination (A6254-6255 and A6256-6257) were used for measuring the expression of WOPl.
- the primer combinations amplify different parts of the mRNA/cDNA.
- Two household genes (C1PP2A and C1YLS8) were added as control.
- the expression was normalized to one of the household genes.
- the wild type young leaf sample was put at 100%.
- the expression of the wopl mutant allele was essentially similar to the expression of the WOP1 wild type allele in the young leaf and in the developing ovary tissues. For both primer pairs similar results were obtained. This shows that the wopl mutation in the coding sequence has no effect on WOP1 gene expression.
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